CN222637951U - A structure for placing power saving modules - Google Patents

Abstract

The utility model relates to the technical field of electric power equipment, and discloses a structure for placing a power-saving module, including: a support frame, at least one power-saving module and an external cable, the support frame having a support layer, an insulating component being arranged on the support layer; the power-saving module being placed on the insulating component, each power-saving module having a wiring port; one end of the external cable being directly or indirectly electrically connected to the wiring port, and the other end being suitable for being connected to the transformer's output busbar. The power-saving module of the utility model is insulated and placed on the support layer, and each power-saving module is provided with only one wiring port, the power-saving module is connected to the cable through the wiring port, and the power-saving module is connected to the power system at a single point, so that the distribution line has no loop, and the number of external cables is reduced, so as to achieve the purpose of simplifying the distribution line, and effectively solve the problem that the traditional distribution line with a loop is relatively complicated, so that the wiring process is simple and easy to operate, the overall cost is reduced, and it is convenient for later maintenance.

Description

Structure for placing power-saving module

Technical Field

The utility model relates to the technical field of power equipment, in particular to a structure for placing a power saving module.

Background

The power saving module is connected in the power utilization system, is usually connected between the transformer and the load, and can play a role in reducing the power consumption, thereby reducing the energy consumption cost. The energy saving module is typically placed in a cabinet supported by structures in the cabinet to improve safety. Manufacturers are used for improving the competitiveness of the manufacturers and continuously adjusting and optimizing the structure of the cabinet.

However, in the conventional cabinet, the loop system of the distribution line is complex, so that the cable wiring process is complex, the occupied space of the cable after wiring is large, the overall cost is high, the operation is inconvenient and the maintenance is inconvenient.

Disclosure of utility model

In view of the above, the present utility model provides a structure for placing power saving modules to solve the problem of complex distribution lines.

The utility model provides a structure for placing power-saving modules, which comprises a support frame, at least one power-saving module and an external cable, wherein the support frame is provided with a support layer, an insulating assembly is arranged on the support layer, the power-saving modules are placed on the insulating assembly, each power-saving module is provided with a wiring port, one end of the external cable is directly or indirectly electrically connected with the wiring port, and the other end of the external cable is suitable for being connected to an outgoing busbar of a transformer.

The power-saving module has the beneficial effects that the power-saving module is arranged on the supporting layer of the supporting frame in an insulating way by arranging the insulating assembly and placing the power-saving module on the insulating assembly, and only one wiring port is arranged on each power-saving module, the power-saving module is connected with a cable through one wiring port, and the power-saving module is connected in the power-using system in a single point mode, so that a distribution line is loop-free, the number of external cables is reduced, the purpose of simplifying the distribution line is realized, the problem that the traditional distribution line with a loop is complex is effectively solved, the wiring process is simple and easy to operate, the overall cost is reduced, and the post maintenance is convenient.

In an alternative embodiment, the number of the external cables is equal to the number of the power saving modules, one end of each external cable is directly connected with one of the wiring ports, and the other end of each external cable is suitable for being connected to an outgoing busbar of the transformer.

The power-saving device has the beneficial effects that the number of the external cables is equal to that of the power-saving modules, and each power-saving module is directly and electrically connected with the outgoing busbar of the transformer through one external cable, so that the structure is simple, and the connection operation is convenient.

In an alternative embodiment, the number of the supporting layers is one or more, the structure for placing the power saving modules further comprises copper bars, the number of the copper bars is equal to that of the supporting layers, each copper bar is in insulating connection with the corresponding supporting layer and is electrically connected with the wiring port of the power saving module on the supporting layer, a collecting point is arranged on each copper bar, and each copper bar is electrically connected with an external cable through the collecting point, so that the external cable is indirectly and electrically connected with the wiring port.

The electric power saving device has the beneficial effects that the copper bars 5 are arranged on each supporting layer, the electricity saving modules on each supporting layer are electrically connected with the copper bars firstly, and then are electrically connected with the collecting points on the copper bars through the external cables, so that after the currents of the plurality of electricity saving modules on each supporting layer are collected to one position of the collecting points, the electricity saving modules can be connected with the outside through the external cables, and the number of the external cables is reduced through the cooperation of the copper bars and the external cables, so that the electric power saving device is convenient to wire, saves the cost and is convenient to maintain.

In an alternative implementation mode, the structure for placing the power saving module further comprises a first insulator, wherein the first insulator is arranged between the support frame and the copper bar, one end of the first insulator is connected to the support frame, and the other end of the first insulator is connected to the copper bar.

The copper bar and the support frame have the beneficial effects that the first insulator is arranged between the support frame and the copper bar, so that the insulation connection between the copper bar and the support frame is ensured, the insulation is improved, the short circuit between the copper bar and the support frame is avoided, and the safety is improved.

In an alternative implementation mode, the structure for placing the power saving modules further comprises copper noses, wherein the copper noses are connected to the copper bars, the number of the copper noses on each copper bar is equal to the number of the power saving modules on the supporting layer corresponding to the copper bars, and each copper nose is connected with the wiring port on one power saving module through a connecting cable.

The copper wire connection device has the beneficial effects that the copper noses with the same number as the corresponding power saving modules are arranged on the copper bar, each power saving module is electrically connected with the copper noses through one connecting cable, so that the power saving modules are electrically connected with the copper bar, and the copper noses are good in conductivity, simple in structure, convenient to use and stable in connection.

In an alternative implementation mode, the structure for placing the power saving module further comprises fixed line insulating plates, the number of the fixed line insulating plates is equal to that of the external cables, each fixed line insulating plate corresponds to one external cable, the fixed line insulating plates are arranged between the external cables and the supporting frame, and the fixed line insulating plates are fixed on the supporting frame.

The cable fixing insulating plate has the beneficial effects that the cable fixing insulating plate is arranged between the support frame and the external cable, so that the insulativity between the external cable and the support frame is improved, and the safety is improved.

In an alternative embodiment, the structure for placing the power saving module further comprises a support connecting piece, wherein the support connecting piece is connected between the support frame and the wire fixing insulating plate, so that the wire fixing insulating plate is spaced from the support frame and fixes the wire fixing insulating plate.

The cable fixing device has the beneficial effects that the cable fixing insulating plate is fixed by arranging the supporting connecting piece between the supporting frame and the cable fixing insulating plate, so that the stability of the structure is improved, the cable fixing insulating plate is spaced from the supporting frame by the supporting connecting piece, the distance between the cable fixing insulating plate and the supporting frame is increased, namely the distance between the external cable and the supporting frame is increased, and therefore insulation protection is further provided for the external cable, and the safety is improved.

In an alternative embodiment, the insulating assembly comprises a supporting insulating plate, wherein the supporting insulating plate is arranged above the supporting layer, and the power saving module is arranged on one side of the supporting insulating plate away from the supporting layer.

The power-saving support device has the beneficial effects that the power-saving module is arranged on the support insulating plate by arranging the support insulating plate above the support layer, so that the insulation supporting effect on the power-saving module is achieved, the insulation between the power-saving module and the support frame and the insulation between the power-saving modules on different support layers are increased, and the safety is improved.

In an alternative embodiment, the insulation assembly further comprises an insulation strip arranged on one side of the support insulation plate far away from the support layer so as to limit the power saving module.

The power saving module has the beneficial effects that the insulating strips are arranged on the supporting insulating plate and are higher than the upper surface of the supporting insulating plate, and the insulating strips are positioned on the outer side of the power saving module, so that the power saving module can be limited and prevented from shifting, the stability of the power saving module placed on the supporting insulating plate is improved, and the safety of the whole structure is further improved.

In an alternative embodiment, the insulation assembly further comprises a second insulator connected between the support layer and the support insulation plate.

The power-saving module has the beneficial effects that the distance between the supporting insulating plate and the supporting layer is increased by arranging the second insulator between the supporting layer and the supporting insulating plate, so that the distance between the power-saving module and the supporting layer is increased, and the space above and below the supporting frame is utilized to enable the power-saving modules on different supporting layers to have enough safety distance, so that the requirement of insulativity is met.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of a structure for placing a power saving module according to an embodiment of the present utility model;

fig. 2 is a front view of the structure of fig. 1 in which a power saving module is placed;

FIG. 3 is a side view of the structure of FIG. 1 for placing a power saving module;

fig. 4 is an electrical schematic diagram of a power saving module connected in an electrical system according to an embodiment of the present utility model.

Reference numerals illustrate:

1. the power-saving device comprises a supporting frame, 101, a supporting layer, 2, an insulating assembly, 201, a supporting insulating plate, 202, insulating strips, 203, a second insulator, 3, a power-saving module, 301, a wiring port, 4, an external cable, 5, copper bars, 501, a collecting point, 6, a first insulator, 7, a copper nose, 8, a wire fixing insulating plate, 9, a supporting connecting piece, 10, a cabinet body, 11, a main switch, 12, a load, 13, a circuit breaker, 14 and a frequency converter.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The distribution lines corresponding to the power saving modules in the related art are all loop systems, the power saving modules are provided with input ends and output ends, and the input ends and the output ends are respectively connected with the cables, so that the cable distribution in the cabinet is complex.

Embodiments of the present utility model are described below with reference to fig. 1 to 4.

According to an embodiment of the present utility model, in one aspect, there is provided a structure for placing a power saving module, as shown in fig. 1 to 3, the structure for placing the power saving module includes a support frame 1, at least one power saving module 3, and an external cable 4. The support frame 1 is provided with a support layer 101, an insulating assembly 2 is arranged on the support layer 101, power saving modules 3 are arranged on the insulating assembly 2, each power saving module 3 is provided with a wiring port 301, one end of an external cable 4 is directly or indirectly electrically connected with the wiring port 301, and the other end of the external cable is suitable for being connected to an outgoing busbar of a transformer. The power saving module 3 is electrically connected to an outgoing busbar of the transformer through an external cable 4, and further, the outgoing busbar of the transformer is a busbar copper.

The structure of placing power saving module of this embodiment is through setting up insulating subassembly 2 on the supporting layer 101 of support frame 1 to place power saving module 3 on insulating subassembly 2, realize placing power saving module 3 on supporting layer 101 in an insulating way, and through setting up that every power saving module 3 has only a wiring mouth 301, power saving module 3 is connected with the cable through a wiring mouth 301, power saving module 3 single-point connection is in the power system, then the distribution lines is not the return circuit, the quantity of external cable 4 has been reduced, the purpose of simplifying the distribution lines is realized, the comparatively complicated problem of traditional distribution lines that has the return circuit has been effectively solved, make the wiring process simple easy operation, bulk cost reduces and be convenient for later maintenance.

It should be noted that, the power saving module 3 of this embodiment utilizes the novel material of quantum entropy energy reduction, weakens unordered collision of free electron from the microcosmic level, increases the order of free electron, improves conductivity, reduces the loss to reach the purpose of economizing on electricity, a wiring mouth 301 of this power saving module 3 passes through a cable to be connected to the power consumption system, the distribution line is not having the return circuit, as shown in the electrical schematic diagram of fig. 4, on the female copper bar of transformer (not shown in the figure) outgoing line, each looks inserts power saving module 3 respectively, power saving module 3 single point connection is in the power consumption system, master switch 11 is used for controlling the break-make of whole circuit, can include one or more loads 12 in the power consumption system, each load 12 passes through the break-make of this circuit branch road of circuit control, load 12 place branch road can also set up converter 14.

The number of the supporting layers 101 may be one, two, three or more, according to the actual requirement, when the number of the supporting layers 101 is multiple, the supporting layers 101 are distributed at intervals along the up-down direction indicated by the arrow in fig. 2, so as to ensure that the power saving modules 3 on different supporting layers 101 are spaced along the up-down direction, a certain safety distance is provided, insulation is ensured, the power saving modules 3 placed on the supporting layers 101 may be high-voltage power saving modules or low-voltage power saving modules, the power saving modules 3 have different types, the power saving modules 3 of different types have different capacities, and may have capacities of 100kW (kilowatts), 200kW, 300kW, 400kW, 500kW, 700kW, 1000kW and the like, the number of the power saving modules is selected according to the actual requirement, that is, the power saving modules capacity is configured according to the actual load size of the transformer, for example, for a 1000kW load, two power saving modules 3 connected on each phase may be selected, and the number of the power saving modules 3 may be selected to meet the requirement of the power saving modules of 200 kW.

In one embodiment, the structure for placing the power saving module further includes copper bars 5, where the number of copper bars 5 is equal to the number of supporting layers 101, each copper bar 5 is connected with the corresponding supporting layer 101 in an insulating manner, and is electrically connected to the wiring port 301 of the power saving module 3 on the supporting layer 101, a collection point 501 is disposed on each copper bar 5, and each copper bar 5 is electrically connected to one external cable 4 through one collection point 501, so that the external cable 4 is indirectly electrically connected to the wiring port 301. It should be noted that, the collection point 501 is a connection point on the copper bar 5, the power saving modules 3 may be high voltage power saving modules, and the high voltage power saving modules correspond to thicker cables, when at least two power saving modules 3 are placed on each supporting layer 101, if each power saving module 3 is directly connected to the outside through one cable, multiple cables are arranged side by side, so that occupied space is larger, by arranging one copper bar 5 on each supporting layer 101, the power saving modules 3 on each supporting layer 101 are electrically connected with the copper bar 5 first, and then are electrically connected with the collection point 501 on the copper bar 5 through one external cable 4, so that after the currents of the power saving modules 3 on each supporting layer 101 are collected to one place of the collection point 501, the power saving modules can be connected with the outside through one external cable 4, and the cooperation of the copper bar 5 and the external cable 4, so that the number of the external cables 4 is reduced, the cable wiring is convenient, the cost is saved, and the maintenance is convenient. For example, for a common three-phase three-wire or three-phase four-wire power system, three or four external cables 4 are required to be connected with the transformer outlet busbar, and correspondingly, the supporting layer 101 on the supporting frame 1 is arranged to be three or four layers.

Preferably, the electricity-saving module 3 is a quantum electricity-saving module, the quantum electricity-saving module weakens unordered collision of free electrons from a microcosmic level, increases the order of the free electrons, improves the conductivity, reduces the loss, and finally reduces the electricity consumption, and in the whole process, the temperature, the volume and the property of the product are not changed, no unsafe factors are generated, the universality is strong, and the application range is wide.

In addition, in other embodiments (not shown in the figures), the number of external cables 4 is equal to the number of power saving modules 3, and one end of each external cable 4 is directly connected to one of the connection ports 301 and the other end is adapted to be connected to an outlet busbar of a transformer. Through setting up the quantity of external cable 4 and the quantity of economize on electricity module 3 equal, every economize on electricity module 3 is directly connected with the female row electricity of being qualified for next round of competitions of transformer through an external cable 4, simple structure, the connection operation of being convenient for. Preferably, the power saving module is a low voltage power saving module, and the cable used by the low voltage power saving module is thinner than the cable used by the high voltage power saving module, so that each power saving module 3 can be directly connected with the outside through one external cable 4 without occupying excessive space.

In one embodiment, the structure for placing the power saving module further comprises a first insulator 6, wherein the first insulator 6 is arranged between the support frame 1 and the copper bar 5, one end of the first insulator 6 is connected to the support frame 1, and the other end of the first insulator is connected to the copper bar 5. Through set up first insulator 6 between support frame 1 and copper bar 5, guarantee the insulating connection of copper bar 5 and support frame 1, improve the insulativity, avoid copper bar 5 and support frame 1 to take place the short circuit to improve the security. The insulator is a device capable of withstanding voltage and mechanical stress, has good insulativity, high strength, mature technology and easy acquisition, and can be selected according to the requirements.

In one embodiment, the structure for placing the power saving modules further comprises copper noses 7, wherein the copper noses 7 are connected to the copper bars 5, the number of the copper noses 7 on each copper bar 5 is equal to the number of the power saving modules 3 on the supporting layer 101 corresponding to the copper bars 5, and each copper nose 7 is connected with a wiring port 301 on one power saving module 3 through a connecting cable (not shown in the figure). The connection cable is used for connecting the power saving module 3 and the copper bar 5, one end of the connection cable is electrically connected with the wiring port 301 on the power saving module 3, and the other end of the connection cable is electrically connected with the copper nose 7 on the copper bar 5. Through set up the copper nose 7 that equals rather than corresponding electricity-saving module 3 quantity on copper bar 5, every electricity-saving module 3 passes through a connecting cable and copper nose 7 electric connection, realizes that electricity-saving module 3 and copper bar 5's electricity is connected, and copper nose 7 conductive properties is good, simple structure, convenient to use, connection is stable.

In one embodiment, the structure for placing the power saving module further comprises wire fixing insulating plates 8, the number of the wire fixing insulating plates 8 is equal to that of the external cables 4, each wire fixing insulating plate 8 corresponds to one external cable 4, the wire fixing insulating plates 8 are arranged between the external cables 4 and the support frame 1, and the wire fixing insulating plates 8 are fixed on the support frame 1. By arranging the wire fixing insulating plate 8 between the support frame 1 and the external cable 4, the insulation between the external cable 4 and the support frame 1 is increased, so that the safety is improved. Preferably, when the number of the supporting layers 101 is three, three solidus insulating plates 8 are correspondingly arranged, wherein, along the width direction indicated by the arrow in fig. 2, one solidus insulating plate 8 is respectively arranged at two sides of the supporting frame 1, and one solidus insulating plate 8 corresponding to the lowest supporting layer 101 is arranged in the middle, so that the space can be reasonably utilized.

In one embodiment, the connecting holes are formed in the wire fixing insulating plate 8, and the external cable 4 is connected to the wire fixing insulating plate 8 through the binding belt, so that the stability of the external cable 4 is improved, and the binding belt is simple in structure, low in price and convenient to assemble and disassemble.

In one embodiment, the structure for placing the power saving module further comprises a supporting connecting piece 9, wherein the supporting connecting piece 9 is connected between the support frame 1 and the wire fixing insulating plate 8, so that the wire fixing insulating plate 8 is spaced from the support frame 1 and fixes the wire fixing insulating plate 8. Through setting up support connecting piece 9 between support frame 1 and solidus insulation board 8, fix solidus insulation board 8, increase the stability of structure, it is spaced apart with support frame 1 to be at the same time with solidus insulation board 8 through support connecting piece 9, increases the distance between solidus insulation board 8 and the support frame 1, increases the distance between external cable 4 and the support frame 1 promptly to further provide insulation protection to external cable 4, increase the security.

Preferably, the support connector 9 is fixedly connected with the support frame 1 and detachably connected with the wire fixing insulating plate 8. Optionally, the support frame 1 is made of steel, the support connecting piece 9 is welded on the support frame 1, the wire fixing insulating plate 8 is provided with a first mounting hole, the support connecting piece 9 is provided with a second mounting hole, and bolts sequentially penetrate through the first mounting hole and the mounting hole to connect the wire fixing insulating plate 8 on the support connecting piece 9.

In one embodiment, the insulating assembly 2 comprises a supporting insulating plate 201, wherein the supporting insulating plate 201 is arranged above the supporting layer 101, and the power saving module 3 is arranged on one side of the supporting insulating plate 201 away from the supporting layer 101. Wherein, the upper direction refers to the direction of the arrow in fig. 2. Through setting up support insulation board 201 in the top of supporting layer 101 to place economize on electricity module 3 on supporting insulation board 201, play the insulating support effect to economize on electricity module 3, increase the insulating nature between economize on electricity module 3 and the support frame 1 and the insulating nature between the economize on electricity module 3 on different supporting layer 101, thereby improve the security. The insulating board is insulating material, and insulating properties is good, easily obtains and simple to operate.

In one embodiment, the insulating assembly 2 further comprises an insulating bar 202, wherein the insulating bar 202 is arranged on the side of the supporting insulating plate 201 far away from the supporting layer 101 so as to limit the power saving module 3. The insulating strip 202 is arranged on the supporting insulating plate 201 and close to the edge, the insulating strip 202 is arranged on the supporting insulating plate 201, the insulating strip 202 is higher than the upper surface of the supporting insulating plate 201, the insulating strip 202 is arranged on the outer side of the electricity-saving module 3, the electricity-saving module 3 can be limited, the electricity-saving module 3 is prevented from shifting, the stability of the electricity-saving module 3 placed on the supporting insulating plate 201 is improved, and the safety of the whole structure is further improved.

In one embodiment, the insulation assembly 2 further comprises a second insulator 203, the second insulator 203 being connected between the support layer 101 and the support insulation plate 201. By arranging the second insulator 203 between the supporting layer 101 and the supporting insulating plate 201, the distance between the supporting insulating plate 201 and the supporting layer 101 is increased, so that the distance between the power saving module 3 and the supporting layer 101 is increased, and the space above and below the supporting frame 1 is utilized to enable the power saving modules 3 on different supporting layers 101 to have enough safety distance, so that the requirement of insulativity is met. Preferably, each insulation assembly 2 comprises a plurality of second insulators 203, and the plurality of second insulators 203 are distributed on the supporting layer 101 at intervals, so that on one hand, the stability of supporting is improved, and on the other hand, the whole weight of the insulation assembly 2 can be reduced, and the cost is saved.

Preferably, as further shown in fig. 2, the copper bar 5 on each supporting layer 101 is located at the middle position of the side edge of the supporting layer 101 along the width direction, the copper bar 5 is composed of a plurality of conductive bars, a first conductive bar is arranged at the position flush with the supporting layer 101, a second conductive bar is arranged at the position flush with the supporting insulating plate 201, the first conductive bar and the second conductive bar are connected through two third conductive bars, a collecting point 501 is located on the first conductive bar, a copper nose 7 is located on the second conductive bar, for the supporting frame 1 with three supporting layers 101, the copper bar 5 corresponding to the uppermost supporting layer 101 and the middle supporting layer 101 extends to a position close to the edge of the supporting layer 101 along the width direction, the extending direction of the first conductive bar of the copper bar 5 corresponding to the uppermost supporting layer 101 is opposite to that of the middle supporting layer 101, the collecting point 501 is located at the tail end of the extending part of the first conductive bar, the first collecting point 501 is located at the first non-extending of the supporting bar 5 corresponding to the lowest supporting layer 101, and the first collecting point 501 is located at the middle point of the supporting bar. Correspondingly, an external cable 4 is distributed on the left side, the right side and the middle in the width direction, the left space and the right space of the structure are reasonably utilized, and the layout of the cable is optimized. Wherein the width direction refers to the "width direction" indicated by the arrow in fig. 2. It will be appreciated that, as an alternative embodiment, the copper bar 5 may also comprise only a first conductive strip, where the collection point 501 and the copper nose 7 are located, and where the copper nose 7 is spaced from the collection point 501.

It should be noted that, for the high-voltage power saving module, the insulating assembly 2 may include the supporting insulating plate 201, the insulating strip 202 and the second insulator 203 at the same time to meet the insulation requirement, and for the low-voltage power saving module, the insulating assembly 2 may include only the supporting insulating plate 201 and the insulating strip 202, and the insulating requirement can be met without the second insulator 203.

In one embodiment, the structure for placing the power saving module further comprises a cabinet body 10, the support frame 1 and all parts connected to the support frame 1 are located in the cabinet body 10, and the cabinet body 10 plays a role in further safety protection.

The structure for placing the power saving module in the embodiment skillfully utilizes the up-down left-right space in the cabinet body 10 to enable the three-phase or four-phase power saving module 3 to have enough safety distance, meets the requirement of insulativity, simultaneously, the external cable 4 is supported by taking the wire fixing insulating plate 8 as an intermediary, and finally, the external cable and the power saving module 3 are gathered through the gathering point 501 on the copper bar 5, so that the cable wiring is relatively convenient, the insulation safety is well met, and meanwhile, the cost is low, and the maintenance is convenient.

Although embodiments of the present utility model have been described in connection with the accompanying drawings, various modifications and variations may be made by those skilled in the art without departing from the spirit and scope of the utility model, and such modifications and variations fall within the scope of the utility model as defined by the appended claims.

Claims (10)

1. A structure for placing a power-saving module, characterized by comprising: A support frame (1) having a support layer (101), wherein an insulating component (2) is arranged on the support layer (101); at least one power-saving module (3), the power-saving module (3) being placed on the insulating component (2), and each of the power-saving modules (3) having a wiring port (301); An external cable (4), one end of which is directly or indirectly electrically connected to the wiring port (301), and the other end of which is suitable for being connected to an output busbar of a transformer. 2. The structure for placing the power-saving module according to claim 1 is characterized in that the number of the external cables (4) is equal to the number of the power-saving modules (3), one end of each of the external cables (4) is directly connected to one of the wiring ports (301) and the other end is suitable for connection to the outgoing busbar of the transformer. 3. The structure for placing the power-saving module according to claim 1 is characterized in that the number of the supporting layers (101) is one or more, and the structure for placing the power-saving module also includes: copper busbars (5), the number of the copper busbars (5) is equal to the number of the supporting layers (101), each of the copper busbars (5) is insulated and connected to the corresponding supporting layer (101), and is electrically connected to the wiring port (301) of the power-saving module (3) on the supporting layer (101), each of the copper busbars (5) is provided with a collection point (501), and each of the copper busbars (5) is electrically connected to an external cable (4) through the collection point (501), so that the external cable (4) is indirectly electrically connected to the wiring port (301). 4. The structure for placing the power-saving module according to claim 3 is characterized in that it also includes: a first insulator (6), the first insulator (6) is arranged between the support frame (1) and the copper busbar (5), one end of the first insulator (6) is connected to the support frame (1) and the other end is connected to the copper busbar (5). 5. The structure for placing the power-saving module according to claim 3 is characterized in that it also includes: a copper nose (7), the copper nose (7) is connected to the copper bus (5), the number of the copper noses (7) on each copper bus (5) is equal to the number of the power-saving modules (3) on the supporting layer (101) corresponding to the copper bus (5), and each of the copper noses (7) is connected to the wiring port (301) on one of the power-saving modules (3) via a connecting cable. 6. The structure for placing the power-saving module according to claim 3 is characterized in that it also includes: a fixed-line insulating plate (8), the number of the fixed-line insulating plates (8) is equal to the number of the external cables (4), each of the fixed-line insulating plates (8) corresponds to one external cable (4), the fixed-line insulating plate (8) is arranged between the external cable (4) and the support frame (1), and the fixed-line insulating plate (8) is fixed on the support frame (1). 7. The structure for placing the power-saving module according to claim 6 is characterized in that it also includes: a supporting connector (9), wherein the supporting connector (9) is connected between the supporting frame (1) and the fixed-line insulating plate (8) so as to space the fixed-line insulating plate (8) from the supporting frame (1) and fix the fixed-line insulating plate (8). 8. The structure for placing the power-saving module according to any one of claims 1 to 7 is characterized in that the insulating component (2) includes: a supporting insulating plate (201), the supporting insulating plate (201) is arranged above the supporting layer (101), and the power-saving module (3) is placed on a side of the supporting insulating plate (201) away from the supporting layer (101). 9. The structure for placing the power-saving module according to claim 8 is characterized in that the insulating component (2) further comprises: an insulating strip (202), wherein the insulating strip (202) is arranged on a side of the supporting insulating plate (201) away from the supporting layer (101) to limit the power-saving module (3). 10. The structure for placing the power-saving module according to claim 9, characterized in that the insulating component (2) further comprises: a second insulator (203), wherein the second insulator (203) is connected between the supporting layer (101) and the supporting insulating plate (201).