CN110768614A

CN110768614A - Solar device for electric power iron tower

Info

Publication number: CN110768614A
Application number: CN201911093014.1A
Authority: CN
Inventors: 苏俊亮; 慕容啟华; 李茂�; 张珏; 单鲁平; 肖健健; 徐研; 贺伟; 黄明烽; 李定宁; 梁孟孟; 何志斌; 阮耀萱
Original assignee: Guangzhou Power Supply Bureau Co Ltd
Current assignee: Guangzhou Power Supply Bureau of Guangdong Power Grid Co Ltd
Priority date: 2019-11-11
Filing date: 2019-11-11
Publication date: 2020-02-07
Anticipated expiration: 2039-11-11
Also published as: CN110768614B

Abstract

A solar power device for an electric power tower, comprising: the solar panel is arranged on the supporting mechanism; the supporting mechanism comprises a base provided with a main groove, an assembling component connected with the base, a plurality of adjusting mechanisms respectively arranged at two sides of the base and a buckling component connected with the adjusting mechanisms; the assembly component comprises a plurality of first elastic pieces connected with the base and clamping strips movably arranged in the main groove; the first elastic piece is arranged corresponding to the side edge of the main groove; one end of the first elastic piece extends into the main groove; the holding strip and the first elastic piece extend to one end of the main groove and are connected. The clamping strips are attached to the edges of the main grooves by compressing the first elastic pieces, so that an installation space is provided for the solar panel; after placing solar panel in the main recess, loosen the holding strip, the holding strip produces the centre gripping fixed to solar panel's edge to make solar panel install in supporting mechanism fast.

Description

Solar device for electric power iron tower

Technical Field

The invention relates to an electric power iron tower auxiliary device, in particular to a solar device for an electric power iron tower.

Background

In order to realize the monitoring of the power transmission line or the detection of the climate environment on the power iron tower, a camera or other electronic detection equipment may need to be installed on the power iron tower, a power supply needs to be provided for the camera or other electronic detection equipment in the application process of the camera or other electronic detection equipment, the distribution line can be simplified by utilizing the solar mechanism and combining the converter device to supply power to the camera or other electronic detection equipment,

the solar mechanism comprises a mounting bracket and a solar panel, the existing solar mechanism is generally installed on the ground, and the time consumed for fixedly connecting the solar panel to the mounting bracket is long, however, in the process of installing the solar mechanism to the electric iron tower, the mounting bracket is generally required to be installed on the electric iron tower, and then the solar panel is installed on the bracket, so that the problem that the weight of single lifting is too large or the bracket is inconvenient to install is avoided; therefore, on the electric power iron tower, the solar panel is installed on the support and belongs to high-altitude operation, and the existing solar panel installation mechanism is not beneficial to reducing the high-altitude operation time of workers.

Disclosure of Invention

In view of the above, it is necessary to provide a solar device for an electric power tower to solve the problem of long installation time of a solar panel in a solar mechanism.

A solar power device for an electric power tower, comprising: the solar panel is arranged on the supporting mechanism; the supporting mechanism comprises a base provided with a main groove, an assembling component connected with the base, a plurality of adjusting mechanisms respectively arranged at two sides of the base, and a buckling component connected with the adjusting mechanisms; the assembly component comprises a plurality of first elastic pieces connected with the base and clamping strips movably arranged in the main groove; the first elastic piece is arranged corresponding to the side edge of the main groove; one end of the first elastic piece extends into the main groove; the holding strip is connected with one end of the first elastic piece extending into the main groove.

After the solar device for the electric power iron tower is connected to the connecting rod on the electric power iron tower through the buckling component, the base is fixed relative to the buckling component or the connecting rod through the adjusting mechanism; before the solar panel is arranged in the main groove of the base, an operator pushes the clamping strips to compress the first elastic piece, so that the clamping strips are attached to the edge of the main groove to provide an installation space for the solar panel; after placing solar panel in the main recess, loosen the holding strip, the holding strip produces the centre gripping fixed to solar panel's edge to make solar panel install in supporting mechanism fast.

In one embodiment, the base is provided with a plurality of side grooves corresponding to the first elastic pieces on two sides of the main groove respectively; one end of the first elastic piece penetrates through the corresponding side groove; thereby achieving the mounting of the first elastic member.

In one embodiment, the base is provided with side grooves at two sides of the main groove respectively; the side groove extends along the edge of the main groove and is opposite to the end part of the holding strip; the assembly component also comprises a guide block correspondingly connected with the end part of the clamping strip and a roller arranged on the outer side of the guide block; the roller is accommodated in the side groove; the number of the rollers mounted on each guide block is at least two; thereby keeping the moving direction of the holding strip stable.

In one embodiment, the base is provided with a secondary groove at the inner side of the primary groove; an outer frame is arranged on the outer side of the solar panel; the edge of one surface of the outer frame corresponding to the base extends to form a bottom edge; the bottom edge extends in a direction parallel to the surface of the base; the depth of the auxiliary groove corresponds to the thickness of the bottom edge; the bottom edge is accommodated in the auxiliary groove; thereby avoiding the solar panel from loosening under the action of gravity of the solar panel.

In one embodiment, the mounting assembly further comprises a cushion pad connecting the gibs; the buffer pads are connected with one side of the clamping strips, which faces the solar panel; thereby can cushion the holding strip to solar panel's pressure, avoid solar panel impaired.

In one embodiment, the adjusting mechanism comprises a sleeve connected with the base, a support rod movably arranged in the sleeve, and a locking component connected with the sleeve or the support rod; the locking assembly is used for limiting the strut to retract into the sleeve; the buckling assembly is connected with one end of the support rod penetrating out of the sleeve; thereby the buckling component and the connecting rod are kept against, and the fixing of the base relative to the connecting rod is realized.

In one embodiment, a plurality of clamping holes are distributed on the sleeve along the axial direction; the clamping hole penetrates through the side face of the sleeve; the support rod is provided with an adjusting groove with an opening facing the clamping hole; the locking assembly comprises a second elastic piece accommodated in the adjusting groove and a bayonet movably arranged in the adjusting groove in a penetrating manner; the second elastic piece is positioned between the bottom of the adjusting groove and the bayonet; thereby limiting the retraction of the strut into the sleeve.

In one embodiment, the adjusting groove of the strut is provided with a baffle ring; the clamping pin is movably arranged in the retaining ring in a penetrating way; the side surface of the clamping pin extends to form a flange, and the flange is positioned on the inner side of the baffle ring.

In one embodiment, the buckling assembly comprises a bearing piece connected with the adjusting mechanism and a handle piece connected with the bearing piece; one side of the gripper block, which is back to the base, is provided with a mounting groove; thereby the angle difference of the adaptable connecting rod of lock subassembly.

In one embodiment, a first screw hole perpendicular to the axial direction of the adjusting mechanism is formed in the side wall of the gripping block; the buckling assembly further comprises a lock rod piece penetrating through the first screw hole; thereby improving the installation stability of the buckling component.

Drawings

Fig. 1 is a front view of a solar power device for an electric power tower according to an embodiment of the present invention;

fig. 2 is a side view of the solar power plant for an electric power tower shown in fig. 1;

FIG. 3 is a perspective view of the base of FIG. 1;

FIG. 4 is a view of the fitting assembly of FIG. 1 in relation to a solar panel;

FIG. 5 is a view showing the connection between the holding bar and the guide block;

FIG. 6 is a schematic structural view of the adjustment mechanism of FIG. 1;

FIG. 7 is a schematic structural view of an adjustment mechanism in the second embodiment;

FIG. 8 is a view of the adjustment mechanism of FIG. 1 in connection with a snap assembly;

FIG. 9 is a schematic view of the application of the snap assembly in the first condition;

FIG. 10 is a schematic view of the application of the snap assembly in the second condition.

Detailed Description

In order that the invention may be more fully understood, reference will now be made to the following description. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Referring to fig. 1 to 10, a solar device 100 for an electric power iron tower according to an embodiment of the present invention is used to cooperate with a current transformer to supply power to a camera or other electronic detection equipment of the electric power iron tower. The solar device 100 for the electric power iron tower comprises a support mechanism 20 and a solar panel 30 arranged on the support mechanism 20; the supporting mechanism 20 comprises a base 40 provided with a main groove 41, an assembling component 50 connected with the base 40, a plurality of adjusting mechanisms 60a respectively arranged at two sides of the base 40, and a buckling component 70 connected with the adjusting mechanisms 60 a; the assembly component 50 comprises a plurality of first elastic pieces 51 connected with the base 40 and clamping strips 52 movably arranged in the main groove 41; the first elastic member 51 is disposed corresponding to the side edge of the main groove 41; one end of the first elastic member 51 extends into the main groove 41; the holding strip 52 is connected to one end of the first elastic member 51 extending into the main groove 41.

After the base 40 is connected to a connecting rod on the electric power iron tower through the buckling component 70, the base is fixed relative to the buckling component 70 or the connecting rod through the adjusting mechanism 60 a; before the solar panel 30 is installed in the main groove 41 of the base 40, an operator pushes the clamping strip 52 to compress the first elastic member 51, so that the clamping strip 52 is attached to the edge of the main groove 41 to provide an installation space for the solar panel 30; after the solar panel 30 is placed in the main groove 41, the holding strip 52 is released, and the holding strip 52 clamps and fixes the edge of the solar panel 30, so that the solar panel 30 can be quickly installed in the support mechanism 20.

Referring to fig. 3 and 4, in one embodiment, the base 40 is provided with a plurality of side grooves 42 corresponding to the first elastic elements 51 on two sides of the main groove 41; one end of the first elastic element 51 is inserted into the corresponding side groove 42, specifically, one end of the first elastic element 51 inserted into the side groove 42 is connected with the base 40, and the side of the holding strip 52 opposite to the side groove 42 is connected with one end of the first elastic element 51 penetrating out of the side groove 42; alternatively, the first elastic member 51 is a compression spring.

Referring to fig. 3 and 5, in one embodiment, the base 40 is provided with side grooves 43 on two sides of the main groove 41; the side groove 43 extends along the edge of the main groove 41 and is arranged opposite to the end of the holding strip 52; the assembly component 50 further comprises a guide block 53 correspondingly connected with the end part of the clamping strip 52, and a roller 54 arranged on the outer side of the guide block 53; the roller 54 is accommodated in the side groove 43; the number of the rollers 54 mounted on each guide block 53 is at least two; because the number of the rollers 54 mounted on each guide block 53 is at least two, the angle of the guide block 53 relative to the side groove 43 is kept unchanged during the movement of the guide block 53 along the side groove 43, so that the movement direction of the holding strip 52 is kept stable, and the holding strip 52 is prevented from being separated from the main groove 41 to influence the holding of the solar panel 30.

Referring to fig. 3 and 4, in one embodiment, the base 40 is provided with a sub-groove 44 at an inner side of the main groove 41; an outer frame 31 is arranged outside the solar panel 30; a bottom edge 32 extends from the edge of one surface of the outer frame 31 corresponding to the base 40; bottom edge 32 extends in a direction parallel to the surface of base 40; the depth of the secondary groove 44 corresponds to the thickness of the bottom edge 32; bottom edge 32 is received in secondary slot 44; when the holding strip 52 is located on the upper side or the lower side of the solar panel 30, the base 40 provides gravity support through the edge of the outer frame 31 of the solar panel 30, so as to prevent the solar panel 30 from loosening due to the shrinkage of the holding strip 52 caused by the gravity of the solar panel 30; the clip strips 52 define the bottom edge 32 of the outer frame 31 in the sub-groove 44, thereby locking the solar panel 30 in the main groove 41.

Referring to fig. 4 and 5, in one embodiment, the mounting assembly 50 further includes a cushion 55 connected to the clip strip 52; the cushion pad 55 is attached to the side of the gib 52 facing the solar panel 30. So as to buffer the pressure of the holding strip 52 on the solar panel 30 and prevent the solar panel 30 from being damaged; optionally, the cushion pad 55 is made of rubber or sponge.

Referring to fig. 6, in one embodiment, the adjusting mechanism 60a includes a sleeve 61a connected to the base 40, a rod 62a movably disposed in the sleeve 61a, and a locking component 63a connected to the sleeve 61a or the rod 62 a; a locking assembly 63a for limiting retraction of the strut 62a into the sleeve 61 a; the snap assembly 70 connects the end of the post 62a that extends through the sleeve 61 a. When the supporting rods 62a at the two sides of the base 40 are extended to the proper position relative to the sleeve 61a, and the corresponding connecting rods are accommodated in the buckling component 70, the locking component 63a limits the supporting rods 62a to be retracted into the sleeve 61a, so that the buckling component 70 is kept against the connecting rods, and the fixing of the base 40 relative to the connecting rods is realized; in other embodiments, the adjustable connecting rod can be adjusted to be a rod connecting base and a sleeve connecting buckling component.

In one embodiment, a plurality of clamping holes 611 are axially distributed on the sleeve 61 a; the chucking hole 611 penetrates the side surface of the sleeve 61 a; the support rod 62a is provided with an adjusting groove 621 with an opening facing the clamping hole 611; the locking assembly 63a includes a second elastic member 631 received in the adjusting groove 621, and a latch 632 movably disposed in the adjusting groove 621; the second elastic member 631 is between the bottom of the adjustment groove 621 and the click pin 632.

Specifically, the second elastic element 631 presses the latch 632 to the outside of the adjustment slot 621, and when the support rod 62a moves relative to the sleeve 61a to a position where the opening of the adjustment slot 621 corresponds to the latch hole 611, the latch 632 passes through the latch hole 611 under the action of the second elastic element 631, so that the sleeve 61a and the support rod 62a are locked, and the support rod 62a is restricted from retracting into the sleeve 61 a; when the pin 632 is pressed to retract back into the groove 621, the restriction between the sleeve 61a and the rod 62a is released, and the adjustment between the sleeve 61a and the rod 62a is restored. Further, to prevent the latch 632 from being released from the adjustment groove 621, a stopper ring 62 is installed in the adjustment groove 621 of the supporting rod 62 a; the bayonet 632 is movably arranged in the baffle ring 62; the latch 632 has a flange 633 extending laterally, and the flange 633 is located inside the retainer ring 62. Alternatively, the support rod 62a is provided with an internal thread inside the adjustment groove 621, and after the click pin 632 is received in the adjustment groove 621, the stop ring 62 is installed in the adjustment groove 621 by a screw-fit, and the stop ring 62 blocks the flange 633.

Referring to fig. 7, in another embodiment of the adjusting mechanism 60b, in order to also achieve the purpose of limiting the retraction of the supporting rod 62b into the sleeve 61b, a window 612 is provided on the sleeve 61 b; the supporting rod 62b is provided with a plurality of tooth grooves 622 which are distributed along the axial direction of the supporting rod 62 b; gullets 622 correspond to windows 612; the locking assembly 63b includes a spring plate 634 pivotally connected to the outer side of the sleeve 61b, and a third elastic member 635 disposed between the spring plate 634 and the sleeve 61 a; one end of the elastic sheet 634 is movably arranged in the window 612; one end of the elastic sheet 634 is provided with a convex tooth 636 corresponding to the tooth socket 622; the opening of the spline 622 is biased toward the spring plate 634, and a third elastic member 635 is disposed between the sleeve 61b and the other end of the spring plate 634. Specifically, when the strut 62b retracts into the sleeve 61b, the convex tooth 636 is naturally clamped into the tooth socket 622 under the guidance of the tooth socket 622, and the strut 62b is limited from further retracting into the sleeve 61b under the abutting between the convex tooth 636 and the tooth socket 622; third resilient member 635 is a compression spring that pushes against the other end of spring 634, holding teeth 636 against post 62 b.

Referring to fig. 8, in one embodiment, the fastening assembly 70 includes a bearing member 71 connected to the adjusting mechanism 60a, and a grip block 72 connected to the bearing member 71; one side of the handle block 72, which is back to the base 40, is provided with a mounting groove 721; specifically, the bearing piece 71 is accommodated in one side of the grip block 72 facing the base 40, the inner ring of the bearing piece 71 is connected with the adjusting mechanism 60a, and the outer ring of the bearing piece 71 is fixedly connected with the grip block 72, so that the direction of the grip block 72 can be freely adjusted relative to the adjusting mechanism 60a, the angle difference of the connecting rods is adapted, the connecting rods of the power tower at two sides of the base 40 are correspondingly accommodated in the installation grooves 721, and then the extension and contraction of the adjusting mechanism 60a are limited, so that the base 40 and the solar panel 30 can be installed between the adjacent connecting rods.

Referring to fig. 9 and 10, in one embodiment, a first screw hole 722 perpendicular to the axial direction of the adjusting mechanism 60a is disposed on a sidewall of the grip block 72; the fastening assembly 70 further includes a locking rod 73 inserted into the first screw hole 722. After the angle iron-shaped connecting rod is accommodated in the installation groove 721, the end part of the locking rod piece 73 abuts against the vertical part of the angle iron-shaped connecting rod, so that repeated collision between the hand grip block 72 and the connecting rod is avoided, and the installation stability of the buckling assembly 70 is improved; further, a washer 74 is attached to an end of the locking lever member 73 to reduce a pressure generated to a vertical portion of the diagonal iron-shaped link.

In the embodiment, after the base is connected to the connecting rod on the electric iron tower through the buckling component, the base is fixed relative to the buckling component or the connecting rod through the adjusting mechanism; before the solar panel is arranged in the main groove of the base, an operator pushes the clamping strips to compress the first elastic piece, so that the clamping strips are attached to the edge of the main groove to provide an installation space for the solar panel; after placing solar panel in the main recess, loosen the holding strip, the holding strip produces the centre gripping fixed to solar panel's edge to make solar panel install in supporting mechanism fast.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A solar device for an electric power tower, comprising: the solar panel is arranged on the supporting mechanism; the supporting mechanism comprises a base provided with a main groove, an assembling component connected with the base, a plurality of adjusting mechanisms respectively arranged at two sides of the base, and a buckling component connected with the adjusting mechanisms; the assembly component comprises a plurality of first elastic pieces connected with the base and clamping strips movably arranged in the main groove; the first elastic piece is arranged corresponding to the side edge of the main groove; one end of the first elastic piece extends into the main groove; the holding strip is connected with one end of the first elastic piece extending into the main groove.

2. The solar device for the electric power iron tower according to claim 1, wherein the base is provided with a plurality of side grooves corresponding to the first elastic members on two sides of the main groove respectively; one end of the first elastic piece is arranged in the corresponding side groove in a penetrating mode.

3. The solar device for the electric power iron tower according to claim 1, wherein the base is provided with side grooves at both sides of the main groove respectively; the side groove extends along the edge of the main groove and is opposite to the end part of the holding strip; the assembly component also comprises a guide block correspondingly connected with the end part of the clamping strip and a roller arranged on the outer side of the guide block; the roller is accommodated in the side groove; the number of the rollers mounted on each guide block is at least two.

4. The solar device for the electric power iron tower according to claim 3, characterized in that the base is provided with an auxiliary groove inside the main groove; an outer frame is arranged on the outer side of the solar panel; the edge of one surface of the outer frame corresponding to the base extends to form a bottom edge; the bottom edge extends in a direction parallel to the surface of the base; the depth of the auxiliary groove corresponds to the thickness of the bottom edge; the bottom edge is accommodated in the auxiliary groove.

5. The solar power plant for electric power towers according to claim 1, characterized in that said fitting assembly further comprises a buffer pad connecting said clip strips; the buffer pad is connected with one side of the clamping strip, which faces the solar panel.

6. The solar device for the electric power iron tower according to claim 1, wherein the adjusting mechanism comprises a sleeve connected with the base, a support rod movably arranged in the sleeve, and a locking component connected with the sleeve or the support rod; the locking assembly is used for limiting the strut to retract into the sleeve; the buckling component is connected with one end of the support rod penetrating out of the sleeve.

7. The solar device for the electric power iron tower according to claim 6, wherein a plurality of clamping holes are axially distributed on the sleeve; the clamping hole penetrates through the side face of the sleeve; the support rod is provided with an adjusting groove with an opening facing the clamping hole; the locking assembly comprises a second elastic piece accommodated in the adjusting groove and a bayonet movably arranged in the adjusting groove in a penetrating manner; the second elastic piece is positioned between the bottom of the adjusting groove and the clamping pin.

8. The solar device for the electric power iron tower according to claim 7, wherein a baffle ring is installed in the adjusting groove of the support rod; the clamping pin is movably arranged in the retaining ring in a penetrating way; the side surface of the clamping pin extends to form a flange, and the flange is positioned on the inner side of the baffle ring.

9. The solar device for the electric power iron tower according to claim 1, wherein the buckling assembly comprises a bearing member connected with the adjusting mechanism and a gripping block connected with the bearing member; one side of the gripper block back to the base is provided with a mounting groove.

10. The solar device for the electric power iron tower as claimed in claim 9, wherein a first screw hole perpendicular to the axial direction of the adjusting mechanism is formed in a side wall of the grip block; the buckling assembly further comprises a lock rod piece arranged in the first screw hole in a penetrating mode.