CN216489781U - Join in marriage and become dynamic increase holding light of change and store up integrated device - Google Patents

Abstract

The utility model is applicable to the technical field related to power control, and provides a distribution transformation dynamic capacity-increasing light storage integrated device, which comprises a main frame body, the main frame body is internally provided with a frame assembly, the frame assembly is provided with a battery part, a monitoring part and a power conversion part, the upper end of the main frame body is fixedly connected with a photovoltaic part, the side surface of the main frame body is connected with a communicating pipe, the frame component is also provided with a battery heat dissipation component, the frame component and the battery radiating component are arranged to radiate the heat of the battery part through the battery radiating component, the position of the frame component is adjusted, a battery heat dissipation component is arranged at the corresponding position of the battery part, through battery cooling module's setting solution when the power consumption peak, the battery can become the temperature than higher because of work load, if serious, can influence the problem of the normal work of battery even.

Description

Join in marriage and become dynamic increase holding light of change and store up integrated device

Technical Field

The utility model belongs to the technical field related to power control, and particularly relates to a distribution transformer dynamic capacity-increasing light storage integrated device.

Background

Along with economic development and social progress of China, industrial and agricultural production and civil electricity consumption also rise year by year, the electricity consumption demand is in a diversified trend, the power supply requirement for an electric power department is higher and higher, and in many rural power grid areas covered by national power grid companies, due to the fact that local grid structures are weak, the guarantee of power supply is still a prominent problem, particularly, the annual power consumption load rate is low, peak power consumption is time-phased or seasonal, peak loads are prominent in a specific period, distribution change of a transformer area, line overload and low voltage of users are often caused, and the power supply capacity cannot be guaranteed.

The existing device has long-term progress in the aspects of solving the problem of heavy overload operation of the distribution transformer, avoiding equipment accidents and improving power supply quality and power supply reliability, but the existing device has some defects, and when the power consumption peak is reached, the battery can become higher in temperature due to workload, and the normal work of the battery can be influenced even if the battery is serious.

SUMMERY OF THE UTILITY MODEL

The utility model provides a distribution-transformation dynamic capacity-increasing light storage integrated device, and aims to solve the problem that a battery can be heated to a higher temperature due to work load and even can influence the normal work of the battery if the battery is serious in power utilization peak.

The utility model is realized in such a way that a distribution transformation dynamic capacity-increasing light storage integrated device comprises a main frame body, wherein a frame assembly is arranged in the main frame body, a battery part, a monitoring part and a power conversion part are arranged on the frame assembly, the upper end of the main frame body is fixedly connected with a photovoltaic part, the side surface of the main frame body is connected with a communicating pipe, and a battery heat dissipation assembly is also arranged on the frame assembly and dissipates heat to the battery part through the battery heat dissipation assembly.

Preferably, the frame subassembly includes the motor, motor fixed connection is in main framework, the reciprocal lead screw of output fixedly connected with of motor, the outside of reciprocal lead screw is rotated and is connected with reciprocal slider, the vertical board of the lower extreme fixedly connected with of reciprocal slider, a plurality of first joint grooves have been seted up on the vertical board, the joint has horizontal board in the first joint inslot, a plurality of second joint grooves with horizontal board complex have been seted up to the side of main framework.

Preferably, battery radiator unit includes the shell, fixedly connected with cooling pump in the shell, the output of cooling pump is connected with the cooler through first connecting pipe, be provided with the coolant liquid in the first connecting pipe, the first funnel of fixedly connected with on the cooler, still fixedly connected with aspiration pump in the shell, the output and the second connecting pipe of aspiration pump are connected, the second connecting pipe falls into the multistage, and every section the second connecting pipe is connected with the second funnel respectively.

Preferably, a stabilizing component for fixing and stabilizing the monitoring part is arranged on the transverse plate.

Preferably, the stabilizing component comprises a first fixing plate which is symmetrically arranged and is fixedly connected with the transverse plate, a fixed inner rod is fixedly connected to the side face of the first fixing plate, a fixed outer rod is slidably connected to the outer side of the fixed inner rod, a connecting groove is formed in the fixed outer rod, the fixed inner rod is connected with the connecting groove through a first elastic piece, the other end of the fixed outer rod is connected with a second fixing plate, and the second fixing plate is slidably connected with the monitoring part.

Preferably, the first elastic member is a spring.

Compared with the prior art, the embodiment of the application mainly has the following beneficial effects:

1. through the arrangement of the frame assembly and the battery heat dissipation assembly, the position of the frame assembly can be adjusted according to the positions of various devices, the battery heat dissipation assembly is arranged at the corresponding position of the battery part, and the problem that the battery can be heated to a higher temperature due to the work load and even can affect the normal work of the battery when the power consumption peak is high is solved through the arrangement of the battery heat dissipation assembly;

2. through the setting of stabilizing the subassembly, the elastic force effect of first elastic component for the side of second fixed plate butt at the control portion is stabilized fixedly to the control portion.

Drawings

FIG. 1 is a schematic diagram of an overall structure of a distribution-transformation dynamic capacity-increasing optical storage integrated device provided by the present invention;

fig. 2 is a schematic front view of a distribution-transformation dynamic capacitance-increasing optical storage integrated device provided by the utility model.

Fig. 3 is a schematic rear view structure diagram of a distribution-transformation dynamic capacity-increasing optical storage integrated device provided by the utility model.

Fig. 4 is a schematic structural diagram of a connection between a fixed inner rod and a fixed outer rod in a distribution-transformation dynamic capacitance-increasing optical storage integrated device provided by the utility model.

Fig. 5 is a schematic view of an overall structure of a battery heat dissipation assembly in a distribution-transformation dynamic capacitance-increasing integrated optical storage device according to the present invention.

Notations for reference numerals: 1. a main frame body; 2. a frame assembly; 201. a motor; 202. a reciprocating screw rod; 203. a reciprocating slide block; 204. A vertical plate; 205. a first clamping groove; 206. a transverse plate; 207. a second clamping groove; 3. a battery section; 4. a monitoring section; 5. A power conversion unit; 6. a photovoltaic section; 7. a communicating pipe; 8. a battery heat dissipation assembly; 801. a housing; 802. a cooling pump; 803. a first connecting pipe; 804. a cooling machine; 805. a first hopper; 806. an air pump; 807. a second connecting pipe; 808. a second hopper; 9. a stabilizing assembly; 901. a first fixing plate; 902. fixing the inner rod; 903. fixing the outer rod; 904. connecting grooves; 905. a first elastic member; 906. and a second fixing plate.

Detailed Description

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 application belongs; the terminology used in the description of the application herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "including" and "having," and any variations thereof, in the description and claims of this application and the description of the above figures are intended to cover non-exclusive inclusions. The terms "first," "second," and the like in the description and claims of this application or in the above-described drawings are used for distinguishing between different objects and not for describing a particular order.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

The embodiment of the utility model provides a distribution transformation dynamic capacity-increasing optical storage integrated device, which comprises a main frame body 1, wherein a frame assembly 2 is arranged in the main frame body 1, a battery part 3, a monitoring part 4 and a power conversion part 5 are arranged on the frame assembly 2, the upper end of the main frame body 1 is fixedly connected with a photovoltaic part 6, the side surface of the main frame body 1 is connected with a communicating pipe 7, a battery heat dissipation assembly 8 is also arranged on the frame assembly 2, and the battery part 3 is dissipated heat through the battery heat dissipation assembly 8.

Above-mentioned device in the time of practical use, earlier according to the position of various devices, carry out the adjustment of position through frame subassembly 2, place each subassembly on frame subassembly 2 again, then at the relevant position installation battery radiator unit 8 of battery portion 3, through battery radiator unit 8's setting solution when the power consumption peak, the battery can become the temperature ratio than because work load, serious if, can influence the problem of the normal work of battery even.

Further, frame set 2 includes motor 201, motor 201 fixed connection is on main frame body 1, the reciprocal lead screw 202 of output fixedly connected with of motor 201, the outside of reciprocal lead screw 202 is rotated and is connected with reciprocal slider 203, the vertical board 204 of lower extreme fixedly connected with of reciprocal slider 203, a plurality of first joint grooves 205 have been seted up on the vertical board 204, the joint has horizontal board 206 in the first joint groove 205, a plurality of second joint grooves 207 with horizontal board 206 complex are seted up to the side of main frame body 1

When the frame assembly 2 is used in practice, the transverse plates 206 with corresponding quantity are clamped in the second clamping grooves 207 with corresponding positions according to requirements, then the motor 201 is started, the reciprocating screw rod 202 is transferred to rotate so as to drive the reciprocating slide block 203 to move in a reciprocating mode, the vertical plates 204 are driven to move, required intervals are formed, and all assemblies are placed at the moment.

Further, the battery heat dissipation assembly 8 includes a housing 801, a cooling pump 802 is fixedly connected in the housing 801, an output end of the cooling pump 802 is connected with a cooling machine 804 through a first connection pipe 803, a cooling liquid is provided in the first connection pipe 803, a first funnel 805 is fixedly connected on the cooling machine 804, an air suction pump 806 is further fixedly connected in the housing 801, an output end of the air suction pump 806 is connected with a second connection pipe 807, the second connection pipe 807 is divided into multiple sections, and each section of the second connection pipe 807 is respectively connected with the second funnel 808.

When the battery heat dissipation assembly 8 is actually used, the cooling pump 802 drives the cooling liquid cooled by the cooler 804 to circulate in the first connecting pipe 803, and the air cooled at the cooling pump 802 is pumped into the input end of the air pump 806 and then blown out through the second connecting pipe 807 and the second funnels 808 in each direction, so as to cool and dissipate heat of the battery assembly.

Referring to fig. 5, the lateral plate 206 is provided with a stabilizing member 9 for fixing and stabilizing the monitor portion 4.

The stabilizing component 9 comprises a first fixing plate 901 which is symmetrically arranged and fixedly connected with the transverse plate 206, a lateral side fixedly connected with fixed inner rod 902 of the first fixing plate 901, a fixed outer rod 903 which is slidably connected to the outer side of the fixed inner rod 902, a connecting groove 904 which is connected with the fixed outer rod 903 in the fixed outer rod 903, the fixed inner rod 902 is connected with the connecting groove 904 through a first elastic piece 905, the other end of the fixed outer rod 903 is connected with a second fixing plate 906, and the second fixing plate 906 is slidably connected with the monitoring part 4.

The first elastic member 905 is a spring.

When the stabilizing unit 9 is actually used, the second fixing plate 906 abuts against the side surface of the monitoring unit 4 by the elastic force of the first elastic member 905, and the monitoring unit 4 is stably fixed.

In summary, the working principle of the utility model is as follows: firstly, according to the positions of various devices, the positions of the components are adjusted through the frame component 2, then the components are placed on the frame component 2, then the battery heat dissipation component 8 is installed at the corresponding position of the battery part 3, and the problem that the battery can become higher in temperature due to work load and even can affect the normal work of the battery when the power consumption peak is caused is solved through the arrangement of the battery heat dissipation component 8; the cooling pump 802 drives the cooling liquid cooled by the cooler 804 to circulate in the first connecting pipe 803, and the input end of the air pump 806 pumps the air cooled by the cooling pump 802 into the second connecting pipe 807 to blow out the air through the second funnels 808 in each direction, so as to cool and dissipate the heat of the battery assembly; the second fixing plate 906 is abutted against the side surface of the monitor part 4 by the elastic force of the first elastic member 905, and the monitor part 4 is stably fixed.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent replacements, improvements, etc. within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a join in marriage and become developments increase volume light and store up integrated device, includes main framework (1), its characterized in that, be provided with frame set spare (2) in main framework (1), be provided with battery portion (3), control portion (4) and power conversion portion (5) on frame set spare (2), the upper end fixedly connected with photovoltaic portion (6) of main framework (1), the side of main framework (1) is connected with communicating pipe (7), still be provided with battery radiator unit (8) on frame set spare (2), dispel the heat through battery radiator unit (8) battery portion (3).

2. The distribution transformer dynamic capacity-increasing light-storage integrated device as claimed in claim 1, wherein the frame assembly (2) comprises a motor (201), the motor (201) is fixedly connected to the main frame body (1), an output end of the motor (201) is fixedly connected with a reciprocating lead screw (202), a reciprocating slider (203) is rotatably connected to an outer side of the reciprocating lead screw (202), a vertical plate (204) is fixedly connected to a lower end of the reciprocating slider (203), a plurality of first clamping grooves (205) are formed in the vertical plate (204), a transverse plate (206) is clamped in the first clamping grooves (205), and a plurality of second clamping grooves (207) matched with the transverse plate (206) are formed in a side surface of the main frame body (1).

3. The distribution-transformation dynamic capacity-increasing optical storage integrated device as claimed in claim 1, wherein the battery heat dissipation assembly (8) comprises a housing (801), a cooling pump (802) is fixedly connected in the housing (801), an output end of the cooling pump (802) is connected with a cooler (804) through a first connecting pipe (803), a cooling liquid is arranged in the first connecting pipe (803), a first funnel (805) is fixedly connected to the cooler (804), an air pump (806) is further fixedly connected in the housing (801), an output end of the air pump (806) is connected with a second connecting pipe (807), the second connecting pipe (807) is divided into multiple sections, and each section of the second connecting pipe (807) is respectively connected with a second funnel (808).

4. The distribution-transformation dynamic capacity-increasing light-storage integrated device as claimed in claim 2, wherein the transverse plate (206) is provided with a stabilizing component (9) for fixing and stabilizing the monitoring part (4).

5. The distribution-transformation dynamic capacity-increasing optical storage integrated device as claimed in claim 4, wherein the stabilizing component (9) comprises first fixing plates (901) which are symmetrically arranged and fixedly connected with the transverse plate (206), a fixed inner rod (902) is fixedly connected to the side surface of the first fixing plate (901), a fixed outer rod (903) is slidably connected to the outer side of the fixed inner rod (902), a connecting groove (904) is arranged in the fixed outer rod (903), the fixed inner rod (902) is connected with the connecting groove (904) through a first elastic member (905), the other end of the fixed outer rod (903) is connected with a second fixing plate (906), and the second fixing plate (906) is slidably connected with the monitoring part (4).

6. The distribution-transformation dynamic capacity-increasing optical storage integrated device as claimed in claim 5, wherein the first elastic member (905) is a spring.

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