CN220205097U - Off-grid sky imager combination device - Google Patents

Abstract

The utility model provides an off-grid sky imager combination device which is characterized by comprising a support column, an embedded assembly, an energy storage assembly, a solar assembly, a connecting assembly and a sky imager, wherein the support column is arranged on the support column; the top of the embedded assembly is fixedly connected with the bottom of the supporting column, the energy storage assembly, the solar assembly and the connecting assembly are sequentially fixedly connected onto the supporting column from bottom to top, and the sky imager is arranged on the connecting assembly. The utility model has simple structure, can be arranged at places lacking stable power supply and even without power lines, is easy to construct, install and disassemble, and is convenient for subsequent after-sales maintenance and product updating.

Description

Off-grid sky imager combination device

Technical Field

The utility model belongs to the field of monitoring equipment, and particularly relates to an off-grid sky imager combination device.

Background

The sky imager is a continuous automatic monitoring instrument of full sky cloud amount in daytime, is a full-automatic full-color sky imaging system, and provides real-time processing and displaying the sky state in daytime. Because it only works in daytime, can combine together with small-size photovoltaic power generation and small-size energy storage to form a set of device to make it can lay in lacking stable power supply and even do not have the place of power line, and, the device structural design should be satisfied and be liable to construction installation, dismantlement, convenient follow-up after-sale maintenance and product update.

Disclosure of Invention

In view of this, the present utility model provides an off-grid sky imager assembly device, which specifically comprises:

the off-grid sky imager combination device is characterized by comprising a support column, an embedded assembly, an energy storage assembly, a solar assembly, a connecting assembly and a sky imager; the top of the embedded assembly is fixedly connected with the bottom of the supporting column, the energy storage assembly, the solar assembly and the connecting assembly are sequentially fixedly connected onto the supporting column from bottom to top, and the sky imager is arranged on the connecting assembly.

The embedded assembly comprises an upper layer plate and a lower layer plate which are arranged at intervals along the vertical direction and are parallel to each other, through holes through which cables can pass are respectively formed in the centers of the upper layer plate and the lower layer plate, four connecting rods which are uniformly distributed around the through holes and respectively pass through the upper layer plate and the lower layer plate and are fixed, the four connecting rods are respectively fixed with the upper layer plate and the lower layer plate and lock the interval distance between the upper layer plate and the lower layer plate, rod bodies of the lower layer plate penetrating through each connecting rod downwards are respectively outwards bent and extended to form bending sections, rod bodies of the upper layer plate penetrating through each connecting rod upwards are provided with external threads to form screw rod sections, and screw rod ends are matched with fixing nuts to be fixed with the support columns.

The top end of the column tube of the support column is closed, the bottom end of the column tube is fixedly connected with a base plate in a welding mode, and the base plate is provided with a through hole communicated with the bottom end opening of the column tube; the arc notch that supplies pre-buried subassembly to connect usefulness is offered to the bed plate, and the bed plate pastes to support on supplying pre-buried subassembly's upper plate, and the through-hole of column tube bottom opening, bed plate and upper plate's through-hole are just to link up mutually.

Reinforcing rib plates are uniformly and fixedly arranged between the column tube and the base plate.

The energy storage assembly comprises a battery box and two U-shaped connecting rods, an upper U-shaped connecting groove plate and a lower U-shaped connecting groove plate are fixed on the rear side of the battery box body, a pair of short mounting grooves and a pair of long mounting grooves are respectively formed in the groove walls of the rear sides of the upper U-shaped connecting groove plate and the lower U-shaped connecting groove plate, each pair of short mounting grooves is located between each pair of long mounting grooves, the two U-shaped connecting rods are respectively sleeved on the column tube, two straight rod sections on the two sides of the U-shaped connecting rods penetrate through the corresponding short mounting grooves or long mounting grooves of the upper U-shaped connecting groove plate and the lower U-shaped connecting groove plate and are fixed through nuts, and the arc middle sections of the U-shaped connecting rods, the upper U-shaped connecting groove plates and the lower U-shaped connecting groove plates clamp the column tube together.

The notch of the upper U-shaped connecting groove plate faces upwards, and the notch of the lower U-shaped connecting groove plate faces downwards.

The solar module comprises a solar panel and a bracket, wherein the solar panel is fixed on the bracket, and the bracket is fixed on the column body.

The connecting assembly comprises a connecting vertical plate, a square tube beam and a connecting disc, one end of the square tube beam is fixedly welded with the middle part of the connecting vertical plate, the upper tube wall of the other end of the square tube beam is fixedly connected with the connecting disc, and the sky imager is fixed on the connecting disc.

The middle part of the connecting disc is provided with a cable through hole, and the upper pipe wall and the lower pipe wall of the square pipe beam below the cable through hole are also provided with through holes communicated with the cable through hole.

Two pairs of mounting slots are formed in the connecting vertical plate, the connecting vertical plate and the two U-shaped connecting rods are respectively connected with each other through screws to clamp the column tube together, and the connecting assembly is fixedly connected with the supporting column.

The utility model has simple structure, can be arranged at places lacking stable power supply and even without power lines, is easy to construct, install and disassemble, and is convenient for subsequent after-sales maintenance and product updating.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. In the drawings:

FIG. 1 is a schematic front view of the present utility model;

FIG. 2 is a schematic perspective view of the present utility model;

FIG. 3 is a schematic perspective view of a pre-buried assembly;

FIG. 4 is a schematic perspective view of an energy storage tank;

FIG. 5 is a schematic perspective view of a U-shaped connecting rod;

FIG. 6 is a schematic perspective view of a solar module;

FIG. 7 is a schematic perspective view of a connection assembly;

fig. 8 is a perspective view of another view of the connection assembly.

Detailed Description

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model will be described in detail below with reference to the drawings in connection with embodiments.

As shown in the figure, the off-grid sky imager combination device comprises a support column 1, an embedded assembly 2, an energy storage assembly 3, a solar assembly 4, a connecting assembly 5 and a sky imager 6; the embedded assembly 2 is integrally embedded in the ground and serves as the foundation of the whole device, the top of the embedded assembly 2 is fixedly connected with the bottom of the supporting column 1, the energy storage assembly 3, the solar assembly 4 and the connecting assembly 5 are sequentially fixedly connected onto the column body of the supporting column 1 from bottom to top, and the sky imager 6 is installed on the connecting assembly 5. The layout is beneficial to preventing theft, can reduce the length of the circuit, saves the cost and reduces the loss.

In combination with the embodiment of the embedded assembly 2 shown in fig. 3, the embedded assembly 2 comprises an upper layer plate 21 and a lower layer plate 22 which are arranged at intervals along the vertical direction and are parallel to each other, the centers of the upper layer plate 21 and the lower layer plate 22 are respectively provided with through holes 210 and 220 through which cables can pass, and four connecting rods 23 which are uniformly distributed around the through holes and respectively pass through the upper layer plate and the lower layer plate and are fixed, and the four connecting rods can be respectively fixed with the upper layer plate and the lower layer plate in a welding or locking nut mode, so that the interval distance between the upper layer plate and the lower layer plate is locked, and the rod body of each connecting rod which downwards passes through the lower layer plate 22 is respectively outwards bent and extended to form a bending section 232, so that the combination firmness of the whole embedded assembly and a foundation is enhanced; each rod body of the upper plate 21 is provided with an external thread to form a threaded rod section 231, and the threaded rod section 231 is used for being fixed with the support column 1 by matching with a fixing nut (not shown in the figure) in combination with the figure 2, so that the embedded assembly 2 is fixed with the support column 1.

Specifically, the support column 1 comprises a column tube, and the top end opening of the column tube is closed, so that foreign matters, insects and small animals can be prevented from entering the column tube, and the column tube can be rainproof, dampproof and rust-proof;

the bottom end of the column tube 11 is fixedly connected with the base plate 10 by welding, and the base plate 10 is provided with a through hole (not shown) communicated with the bottom end opening of the column tube so that the cable enters the column tube; the base plate 12 is provided with an arc-shaped notch 101 for the penetration of the threaded rod section 231 of the connecting rod 23 of the embedded assembly 2, the base plate 12 is abutted against the upper plate 21 for the embedded assembly 2, the bottom end opening of the column tube, the through hole of the base plate 10 and the through hole 210 of the upper plate 21 are opposite to each other and are communicated, and the embedded assembly 2 is fixed with the support column 1 by the threaded connection and fastening of the nut and the threaded rod section 231 of the connecting rod 23; the arcuate slot 101 facilitates adjustment of the position of the link.

Reinforcing rib plates 102 are uniformly and fixedly connected between the column tube and the base plate 10.

Referring to fig. 2, the column tube 11 is also provided with through holes 111 for the cables to pass through on the tube wall, and the positions and the number of the through holes can be designed according to the needs.

As shown in fig. 4 and 5, the energy storage assembly 3 includes a battery box 30 and two U-shaped connecting rods 31, the battery box 30 is used for storing energy storage batteries and related control devices, a hinged box door 301 is arranged at the front side of the box body of the battery box 30, a door lock is provided to facilitate theft prevention, an upper U-shaped connecting groove plate 303 and a lower U-shaped connecting groove plate 304 are welded and fixed at the rear side of the box body, and specifically, the front groove walls of the upper U-shaped connecting groove plate 303 and the lower U-shaped connecting groove plate 304 are welded and fixed with the rear side of the box body; a pair of short mounting notches 306 and a pair of long mounting notches 303 are respectively formed in the rear side groove walls of the upper U-shaped connecting groove plates 303 and the lower U-shaped connecting groove plates 304, each pair of short mounting notches 306 are located between each pair of long mounting notches 303, the U-shaped connecting rods 31 with the suitable size are conveniently selected according to the diameter of the column tube and matched with the corresponding short mounting notches 306 or long mounting notches 303, specifically, the two U-shaped connecting rods 31 are respectively sleeved on the column tube 11, two straight rod sections 312 of the U-shaped connecting rods 31 penetrate through the corresponding short mounting notches 306 or long mounting notches 303 of the upper U-shaped connecting groove plates 303 and the lower U-shaped connecting groove plates 303 and 304 and are fixed by nuts, and the arc-shaped middle sections 311 of the U-shaped connecting rods 31 and the upper U-shaped connecting groove plates 303 and the lower U-shaped connecting groove plates 304 clamp the column tube 11 together, so that the energy storage assembly 3 and the support column 1 are fixedly connected.

Preferably, the notch of the upper U-shaped connecting trough plate 303 faces upward, and the notch of the lower U-shaped connecting trough plate 304 faces downward, so as to facilitate the screwing operation of the nut and the straight rod section 312 of the U-shaped connecting rod 31.

The solar module 4 comprises a solar panel 41 and a bracket 42, the solar panel 41 is fixed on the bracket 42, the bracket 42 is fixed on a column body, the angle of the solar panel 5 can be adjusted through the bracket 42, and the bracket 42 capable of realizing the functions can have various structures;

the solar cell panel 41 is fixed on the two support angle irons 422 through bolt and nut pairs, the middle lower part of the support angle iron 422 is hinged with one end of the corresponding inclined angle iron 423 respectively, and the other end of the inclined angle iron 423 is hinged with the bottom of the longitudinal angle iron 41 on the corresponding side; the middle lower part of the supporting angle iron 422 can be sequentially provided with a plurality of adjusting through holes 4221 at intervals, each adjusting through hole 4221 corresponds to an angle value, and one adjusting through hole of the middle lower part of the supporting angle iron 422 is hinged with one end of the corresponding oblique angle iron 423 respectively, so that the angle orientation of the solar cell panel 41 fixedly connected to the two supporting angle irons 422 is locked, and if different angles are needed, the penetrating adjusting through holes 4221 can be replaced, thereby being very convenient and fast.

The column tube 11 is clamped between the two arc-shaped hoops 43 and the two corresponding beam angle irons 424, and the screw rod passes through the corresponding mounting hole on the beam angle iron 424 at the end part of the arc-shaped hoops 43 and is locked and fixed by the nut, so that the solar module 4 is fixedly connected with the support column 1.

Referring to fig. 7 and 8, the connection assembly 5 includes a connection vertical plate 51, a square tube beam 52 and a connection disc 53, one end of the square tube beam 52 is welded and fixed to the middle of the connection vertical plate 51, the upper tube wall of the other end of the square tube beam 52 is welded and fixed to the connection disc 53, a cable through hole 530 is formed in the middle of the connection disc 53, and through holes penetrating through the upper tube wall and the lower tube wall of the square tube beam 52 below the cable through hole 530 are formed.

As shown in fig. 2, 7 and 8, the connecting vertical plate 51 is provided with two pairs of mounting slots 510, and the two pairs of mounting slots are respectively and jointly clamped with the two U-shaped connecting rods 54 through screw connection to fix the connecting assembly 5 and the support column 1.

As shown in fig. 2, 7 and 8, the connection pad 53 is further provided with a plurality of mounting holes 531 for screw-fastening the sky imager 6 placed on the connection pad 53.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (10)

1. The off-grid sky imager combination device is characterized by comprising a support column, an embedded assembly, an energy storage assembly, a solar assembly, a connecting assembly and a sky imager; the top of the embedded assembly is fixedly connected with the bottom of the supporting column, the energy storage assembly, the solar assembly and the connecting assembly are sequentially fixedly connected onto the supporting column from bottom to top, and the sky imager is arranged on the connecting assembly.

2. The combination device of the sky imager capable of separating from the net according to claim 1, wherein the embedded assembly comprises an upper layer plate and a lower layer plate which are arranged at intervals along the vertical direction and are parallel to each other, the centers of the upper layer plate and the lower layer plate are respectively provided with a through hole for a cable to pass through, the combination device further comprises four connecting rods which are uniformly distributed around the through holes and respectively pass through the upper layer plate and the lower layer plate and are fixed, the four connecting rods are respectively fixed with the upper layer plate and the lower layer plate and lock the interval distance between the upper layer plate and the lower layer plate, a rod body of each connecting rod which downwards passes through the lower layer plate is respectively outwards bent and extended to form a bending section, a rod body of each connecting rod which upwards passes through the upper layer plate is provided with an external thread to form a screwed rod section, and the screwed rod end is matched with a fixing nut to be fixed with a supporting column.

3. The off-grid sky imager assembly device according to claim 2, wherein the top ends of the column tubes of the support columns are closed, the bottom ends of the column tubes are fixedly connected with a base plate in a welding mode, and the base plate is provided with a through hole communicated with the bottom end opening of the column tubes; the arc notch that supplies pre-buried subassembly to connect usefulness is offered to the bed plate, and the bed plate pastes to support on supplying pre-buried subassembly's upper plate, and the through-hole of column tube bottom opening, bed plate and upper plate's through-hole are just to link up mutually.

4. The combination device of the off-grid sky imager according to claim 3, wherein reinforcing rib plates are uniformly and fixedly connected between the column tube and the base plate.

5. The combination device of the off-grid sky imager according to claim 1, wherein the energy storage assembly comprises a battery box and two U-shaped connecting rods, an upper U-shaped connecting groove plate and a lower U-shaped connecting groove plate are fixed on the rear side of the battery box body, a pair of short mounting notches and a pair of long mounting notches are respectively formed in the rear side groove walls of the upper U-shaped connecting groove plate and the lower U-shaped connecting groove plate, each pair of short mounting notches is located between each pair of long mounting notches, the two U-shaped connecting rods are respectively sleeved on the column tube, straight rod sections on two sides of the U-shaped connecting rods penetrate through the short mounting notches or the long mounting notches of the corresponding upper U-shaped connecting groove plate and the lower U-shaped connecting groove plate and are fixed by nuts, and the arc middle section of the U-shaped connecting rods and the upper U-shaped connecting groove plates and the lower U-shaped connecting groove plates clamp the column tube together.

6. The off-grid sky imager assembly of claim 5, wherein the notch of the upper U-shaped connecting trough plate is facing upward and the notch of the lower U-shaped connecting trough plate is facing downward.

7. The off-grid sky imager assembly of claim 1, wherein the solar module comprises a solar panel and a bracket, the solar panel being secured to the bracket and the bracket being secured to the post.

8. The combination device of the sky imager capable of being separated from a net according to claim 1, wherein the connecting assembly comprises a connecting vertical plate, a square tube beam and a connecting disc, one end of the square tube beam is welded and fixed with the middle part of the connecting vertical plate, the upper tube wall of the other end of the square tube beam is fixedly connected with the connecting disc, and the sky imager is fixed on the connecting disc.

9. The combination device of the off-grid sky imager according to claim 8, wherein a cable through hole is formed in the middle of the connecting disc, and through holes penetrating through the cable through hole are formed in the upper side wall and the lower side wall of the square tube beam below the cable through hole.

10. The off-grid sky imager combination device according to claim 8, wherein the connecting vertical plate is provided with two pairs of mounting slots, and the connecting vertical plate and the two U-shaped connecting rods are respectively and jointly clamped with the column tube through screw connection to realize the fixedly connection of the connecting assembly and the support column.