CN219760650U - Energy storage converter with solar charging function - Google Patents

Abstract

The utility model provides an energy storage converter with a solar charging function, which comprises a cabinet body with a containing cavity, and a converter and a battery cabinet which are arranged in the containing cavity. The top of the cabinet body is inwards sunken to form a first mounting groove and a second mounting groove, a first photovoltaic plate electrically connected with the current transformer is arranged in the first mounting groove, and a second photovoltaic plate electrically connected with the current transformer is arranged in the second mounting groove. The first mounting groove is provided with a first wiring hole communicated with the containing cavity, and the second mounting groove is provided with a second wiring hole communicated with the containing cavity. Therefore, the converter can convert electric energy converted from solar energy into electric energy by the first photovoltaic panel and the second photovoltaic panel into electric current suitable for the battery cabinet, and the electric current is stored by a battery inside the battery cabinet, so that the volume of the energy storage converter is still kept when the energy storage converter is provided with power generation equipment.

Description

Energy storage converter with solar charging function

[ field of technology ]

The utility model relates to the technical field of energy storage equipment, in particular to an energy storage converter with a solar charging function.

[ background Art ]

As is known, energy storage converter devices are devices for controlling the charging and discharging processes of a battery, for performing ac-dc conversion, and for supplying ac loads directly without an electrical network. At present, the existing energy storage converter is generally used for directly charging a battery through an external power supply or a power generation device, does not have power generation equipment, has diesel power generation equipment, and is large in size and inconvenient in product transportation.

Accordingly, the prior art is subject to improvement and development.

[ utility model ]

The utility model aims to provide an energy storage converter with a solar charging function, which is used for solving the problems that the existing energy storage converter generally does not have power generation equipment to directly charge an internal battery or the energy storage converter with the power generation equipment is large in size and inconvenient to transport.

The technical scheme of the utility model is as follows: an energy storage converter with solar charging function, comprising: the cabinet body is provided with a containing cavity, and the converter and the battery cabinet are arranged in the containing cavity;

the current transformer and the battery cabinet are arranged in parallel left and right, and the current transformer is electrically connected with the battery cabinet; the top of the cabinet body is inwards sunken to form a first mounting groove corresponding to the position of the current transformer, the top of the cabinet body is inwards sunken to form a second mounting groove corresponding to the position of the battery cabinet, a first photovoltaic plate electrically connected with the current transformer is mechanically arranged in the first mounting groove, and a second photovoltaic plate electrically connected with the current transformer is mechanically arranged in the second mounting groove; the first mounting groove is provided with a first wiring hole communicated with the cavity, the second mounting groove is provided with a second wiring hole communicated with the cavity, a first conductive wire is connected between the first photovoltaic panel and the current transformer, a second conductive wire is connected between the second photovoltaic panel and the current transformer, the first conductive wire penetrates through the first wiring hole, and the second conductive wire penetrates through the second wiring hole.

Further, the number of the first photovoltaic panels is 4, and the first photovoltaic panels are arranged in the first mounting groove in an orderly manner.

Further, the number of the second photovoltaic panels is 4, and the second photovoltaic panels are arranged in the second mounting groove in an orderly manner.

Further, four end angles of the first photovoltaic panel are locked in the first mounting groove through screws.

Further, the four end angles of the second photovoltaic panel are locked in the second mounting groove through screws.

Further, the number of the first wiring holes is four, and the first wiring holes are respectively positioned below 4 first photovoltaic panels.

Further, the number of the second wiring holes is four, and the second wiring holes are respectively positioned below 4 second photovoltaic panels.

The utility model has the beneficial effects that: compared with the prior art, the first photovoltaic plate and the second photovoltaic plate are arranged at the top of the cabinet body, the first photovoltaic plate and the second photovoltaic plate can be matched with the converter to convert electric energy converted by solar energy into electric energy suitable for the battery cabinet, the electric energy is stored by batteries in the battery cabinet, the batteries in the battery cabinet can be charged when the energy storage converter is externally connected with power generation equipment, and the first photovoltaic plate and the second photovoltaic plate are arranged at the top of the cabinet body, so that the energy storage converter can be conveniently packaged during transportation without damaging the first photovoltaic plate and the second photovoltaic plate. In addition, offer first mounting groove and second mounting groove and install first photovoltaic board, second photovoltaic board respectively on the cabinet body, can promote the aesthetic property of the cabinet body and improve the stability of first photovoltaic board, second photovoltaic board installation.

[ description of the drawings ]

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

fig. 2 is an exploded view of the utility model with a first photovoltaic panel and a second photovoltaic panel after removing a portion of the side wall of the cabinet.

[ detailed description ] of the utility model

The utility model will be further described with reference to the drawings and embodiments.

Referring to fig. 1-2, an energy storage converter with a solar charging function in an embodiment of the utility model is shown.

The energy storage converter with the solar charging function comprises: the cabinet body 1 with the containing cavity 11, and the current transformer 3 and the battery cabinet 2 which are arranged in the containing cavity 11. The current transformer 3 is arranged in parallel with the battery cabinet 2, and the current transformer 3 is electrically connected with the battery cabinet 2. The top of the cabinet body 1 is inwards sunken to form a first mounting groove 12 corresponding to the position of the current transformer 3, the top of the cabinet body 1 is inwards sunken to form a second mounting groove 14 corresponding to the position of the battery cabinet 2, a first photovoltaic panel 5 electrically connected with the current transformer 3 is mechanically arranged in the first mounting groove 12, and a second photovoltaic panel 4 electrically connected with the current transformer 3 is mechanically arranged in the second mounting groove 14. A first wiring hole 13 communicated with the accommodating cavity 11 is formed in the first mounting groove 12, a second wiring hole 15 communicated with the accommodating cavity 11 is formed in the second mounting groove 14, a first conductive wire (not shown in the figure) is connected between the first photovoltaic panel 5 and the current transformer 3, a second conductive wire (not shown in the figure) is connected between the second photovoltaic panel 4 and the current transformer 3, the first conductive wire penetrates through the first wiring hole 13, and the second conductive wire penetrates through the second wiring hole 15.

According to the utility model, the first photovoltaic panel 5 and the second photovoltaic panel 4 are arranged at the top of the cabinet body 1, the first photovoltaic panel 5 and the second photovoltaic panel 4 can be matched with the converter 3 to convert electric energy converted by solar energy into electric current suitable for the battery cabinet 2, and the electric current is stored by batteries in the battery cabinet 2, so that the batteries in the battery cabinet 2 can be charged when the energy storage converter 3 is externally connected with power generation equipment, and the first photovoltaic panel 5 and the second photovoltaic panel 4 are arranged at the top of the cabinet body 1, so that the energy storage converter 3 can be conveniently packaged during transportation without damaging the first photovoltaic panel 5 and the second photovoltaic panel 4, and the problem that the conventional energy storage converter 3 generally does not have power generation equipment to directly charge the internal batteries or the energy storage converter 3 with power generation equipment is large in volume and inconvenient to transport is solved. In addition, the first installation groove 12 and the second installation groove 14 are formed in the cabinet body 1 to respectively install the first photovoltaic panel 5 and the second photovoltaic panel 4, so that the aesthetic property of the cabinet body 1 and the installation stability of the first photovoltaic panel 5 and the second photovoltaic panel 4 can be improved.

Specifically, in one embodiment, to facilitate fixing the first photovoltaic panels 5 and the second photovoltaic panels 4, the number of the first photovoltaic panels 5 is 4, and the first photovoltaic panels are disposed in the first mounting groove 12 in a regular arrangement. The number of the second photovoltaic panels 4 is 4, and the second photovoltaic panels are arranged in the second mounting groove 14 in order. Four end corners of the first photovoltaic panel 5 are locked in the first mounting groove 12 through screws, and four end corners of the second photovoltaic panel 4 are locked in the second mounting groove 14 through screws.

In an embodiment, in order to facilitate the electrical connection between each of the first photovoltaic panel 5 and the second photovoltaic panel 4 and the current transformer 3, the number of the first routing holes 13 is four, and the first routing holes are respectively located below 4 first photovoltaic panels 5. The number of the second routing holes 15 is four, and the second routing holes are respectively positioned below 4 second photovoltaic panels 4.

While the utility model has been described with respect to the above embodiments, it should be noted that modifications can be made by those skilled in the art without departing from the inventive concept, and these are all within the scope of the utility model.

Claims (7)

1. An energy storage converter with solar charging function, comprising: the cabinet body is provided with a containing cavity, and the converter and the battery cabinet are arranged in the containing cavity;

the current transformer and the battery cabinet are arranged in parallel left and right, and the current transformer is electrically connected with the battery cabinet; the top of the cabinet body is inwards sunken to form a first mounting groove corresponding to the position of the current transformer, the top of the cabinet body is inwards sunken to form a second mounting groove corresponding to the position of the battery cabinet, a first photovoltaic plate electrically connected with the current transformer is mechanically arranged in the first mounting groove, and a second photovoltaic plate electrically connected with the current transformer is mechanically arranged in the second mounting groove; the first mounting groove is provided with a first wiring hole communicated with the cavity, the second mounting groove is provided with a second wiring hole communicated with the cavity, a first conductive wire is connected between the first photovoltaic panel and the current transformer, a second conductive wire is connected between the second photovoltaic panel and the current transformer, the first conductive wire penetrates through the first wiring hole, and the second conductive wire penetrates through the second wiring hole.

2. The energy storage converter with solar charging function according to claim 1, wherein the number of the first photovoltaic panels is 4, and the first photovoltaic panels are arranged in the first installation groove in an orderly manner.

3. The energy storage converter with solar charging function according to claim 2, wherein the number of the second photovoltaic panels is 4, and the second photovoltaic panels are arranged in the second installation groove in order.

4. The energy storage converter with solar charging function according to claim 3, wherein four end corners of the first photovoltaic panel are locked in the first installation groove through screws.

5. The energy storage converter with solar charging function according to claim 4, wherein four end corners of the second photovoltaic panel are locked in the second installation groove through screws.

6. The energy storage converter with solar charging function according to claim 5, wherein the number of the first routing holes is four, and the first routing holes are respectively located below 4 first photovoltaic panels.

7. The energy storage converter with solar charging function according to claim 6, wherein the number of the second routing holes is four, and the second routing holes are respectively located below 4 second photovoltaic panels.