CN219371847U - Oilfield well field energy routing cabin - Google Patents

Abstract

The utility model relates to an oilfield well field energy routing cabin. The technical proposal is as follows: the skid-mounted house is fixedly installed on the skid-mounted base, a high-voltage wire inlet, a high-voltage wire outlet, a first low-voltage wire outlet, a second low-voltage wire outlet and a vent are formed in the periphery of the skid-mounted house, a plurality of partitions are installed in the skid-mounted house to form a high-voltage metering chamber, a transformer chamber, a rectifying chamber and an energy storage chamber, the high-voltage metering chamber comprises a high-voltage metering cabinet, a transformer is arranged in the transformer chamber, a rectifying cabinet is arranged in the rectifying chamber, the output end of the rectifying cabinet is connected with the first converging cabinet and the second converging cabinet, one side of the transformer chamber is the energy storage chamber, and more than one group of energy storage batteries are installed in the energy storage chamber. The beneficial effects are that: the problem that each box body is scattered at the well site, the occupation area is large, and the use ratio of the land is reduced is avoided, the adopted skid-mounted structure saves space, the installed capacity of new energy sources of the oilfield well site is improved, and the conversion and utilization efficiency of the new energy sources are further improved.

Description

Oilfield well field energy routing cabin

Technical Field

The utility model relates to an electric control skid-mounted technology for an oilfield well site, in particular to an oilfield well site energy routing cabin.

Background

At present, in the petroleum industry, oil extraction well sites are widely distributed in the field, and along with popularization of new energy sources, a plurality of oil extraction well sites are provided with small-sized solar power stations, so that idle space of the well sites is fully utilized, the power generation proportion of the new energy sources is also improved, but the application of the new energy sources is limited by the existing oil extraction well site conditions. The available space of the well site is limited relatively, and the available space of the well site is limited by a plurality of factors, such as various power control cabinets, transformers, low-voltage power supply boxes, energy storage systems and the like, so that the occupied space is large, and the area of the photovoltaic power station is reduced. Therefore, the method aims at the bottleneck problems of limited space, low conversion and utilization efficiency and the like in the development process of new energy sources in the oilfield well sites, and influences the efficient development and utilization of the new energy sources in the oilfield.

Therefore, there is a need to design and develop an oilfield wellsite energy routing capsule that is adapted to the skid-mounted structure of the oilfield wellsite.

Disclosure of Invention

The utility model aims at overcoming the defects in the prior art, and provides the energy routing cabin for the oilfield well field, which integrates various power control cabinets, transformers, low-voltage power supply boxes, energy storage systems and the like by adopting a skid-mounted structure, so that the space is saved, the installed capacity of new energy sources of the oilfield well field is improved, the conversion and utilization efficiency of the new energy sources is further improved, and technical support is provided for efficient development and utilization of the new energy sources of the oilfield.

The utility model relates to an oilfield well field energy routing cabin, which adopts the technical scheme that: the novel high-voltage power supply system comprises a skid-mounted base (1), a skid-mounted house (2), a vent (3), a high-voltage wire inlet (4), a high-voltage wire outlet (5), a first low-voltage wire outlet (6), a second low-voltage wire outlet (7), a reinforcing column (8) and a door (9), wherein the skid-mounted house (2) is fixedly mounted on the skid-mounted base (1), the door (9) is arranged on one side of the skid-mounted house (2), the high-voltage wire inlet (4), the high-voltage wire outlet (5), the first low-voltage wire outlet (6), the second low-voltage wire outlet (7) and the vent (3) are arranged around, a plurality of partitions are mounted in the skid-mounted house (2), a high-voltage metering chamber, a transformer chamber, a rectifying chamber and an energy storage chamber are formed, the high-voltage metering chamber comprises a high-voltage metering cabinet (1.1), the output end of the high-voltage metering chamber is connected to the transformer (1.4) in the transformer chamber through a high-voltage wire, the output end of the transformer (1.4) is connected to the rectifying cabinet (1.5) in the rectifying chamber through the wire, the first rectifying chamber is connected with the first low-voltage metering chamber (1.6), the second rectifying chamber (1.1.5), and the first low-voltage metering chamber (1.7) is connected to the second rectifying chamber (1.1.5), and the second rectifying chamber is further connected to the high-voltage metering chamber (1.1.1.1). One side of the transformer room is an energy storage room, and more than one group of energy storage batteries are arranged in the energy storage room.

Preferably, the energy storage battery comprises a first energy storage battery (1.11) and a second energy storage battery (1.12), and the first energy storage battery and the second energy storage battery are respectively connected to the solar cell module installed at the well site through a controller.

Preferably, a high-voltage outlet cabinet (1.3) is installed at one side of the high-voltage metering cabinet (1.1), and the output end of the high-voltage outlet cabinet (1.3) is connected to the outer side of the skid-mounted house (2) through a high-voltage outlet (5).

Preferably, the front end of the high-voltage metering cabinet (1.1) is connected with the high-voltage wire inlet cabinet (1.2) through a high-voltage wire, and the output end of the high-voltage wire inlet cabinet (1.2) is connected with the high-voltage metering cabinet (1.1).

Preferably, the high-voltage incoming cabinet (1.2) comprises a high-voltage fuse (1.2.1), a current transformer (1.2.2), a lightning arrester (1.2.3), a combined circuit breaker (1.2.4), a voltage transformer (1.2.5) and an incoming cabinet main body (1.2.8), wherein the incoming cabinet main body (1.2.8) is of a cuboid structure, the high-voltage fuse (1.2.1) and the combined circuit breaker (1.2.4) are arranged in the middle of an inner cavity of the incoming cabinet main body (1.2.8), and one side of the high-voltage fuse (1.2.1) is connected with the combined circuit breaker (1.2.4); a current transformer (1.2.2) and a voltage transformer (1.2.5) are arranged at the lower side of the inner cavity of the wire inlet cabinet main body (1.2.8); and a lightning arrester (1.2.3) is arranged at the bottom of the inner cavity of the incoming line cabinet main body (1.2.8).

Preferably, an electrified display (1.2.6) and a high-voltage protection module (1.2.7) are installed on the side wall of the upper part of the incoming line cabinet main body (1.2.8), and a heat dissipation module (1.2.9) is arranged on the rear side of the upper part of the incoming line cabinet main body (1.2.8).

Preferably, the high-voltage metering cabinet (1.1) comprises a metering cabinet main body (1.1.1), a second current transformer (1.1.2), a high-voltage PT (potential transformer), a CT metering box (1.1.3) and radiating holes (1.1.4), wherein the second current transformer (1.1.2) is arranged at the lower part of an inner cavity of the metering cabinet main body (1.1.1), the high-voltage PT and the CT metering box (1.1.3) are arranged below the second current transformer (1.1.2), and a plurality of groups of radiating holes (1.1.4) are formed in the side wall of the metering cabinet main body (1.1.1).

Preferably, a heat dissipation plate (1.1.5) is arranged at the rear part of the upper side of the high-voltage metering cabinet (1.1), and a plurality of heat dissipation holes are distributed on the heat dissipation plate (1.1.5).

Preferably, the rectifier cabinet comprises a rectifier cabinet main body (1.5.1), a rectifier mounting frame (1.5.2), a disconnecting switch (1.5.3), a four-quadrant rectifier (1.5.4), a second circuit breaker (1.5.5), a cabinet body radiating hole (1.5.6) and a cable gram (1.5.7), wherein the rectifier cabinet main body (1.5.1) is of a cuboid structure, the rectifier mounting frame (1.5.2) is arranged in an inner cavity of the rectifier cabinet main body (1.5.1), the disconnecting switch (1.5.3) is arranged on the upper portion of the rectifier mounting frame (1.5.2), the four-quadrant rectifier is arranged in the middle of the rectifier mounting frame (1.5.2), the second circuit breaker (1.5.5) is arranged on the lower side of the rectifier mounting frame (1.5.2), the cabinet body radiating hole (1.5.6) is formed in the lower side of the rectifier cabinet main body (1.5.1), and the cable gram (1.5.7) is arranged at the bottom of the rectifier cabinet main body (1.5.1).

The beneficial effects of the utility model are as follows: according to the utility model, high-voltage electricity is connected with a high-voltage wire inlet cabinet through a high-voltage wire, the output end of the high-voltage wire inlet cabinet is connected with a high-voltage metering cabinet, the high-voltage wire inlet cabinet meters, then the high-voltage wire inlet cabinet is used for reducing the voltage required by a well site through a transformer, the high-voltage wire inlet cabinet rectifies the voltage through a rectifying cabinet, and then the voltage is output to the outside of the well site through a first confluence cabinet and a second confluence cabinet for operation; in addition, the solar photovoltaic modules distributed on the well site are connected to the first energy storage battery and the second energy storage battery through the controller for storage, and when the well site is maintained at night, the discharging functions of the first energy storage battery and the second energy storage battery are started, the operation cost of the well site is reduced through self-power generation, and the power supply requirement during the well site maintenance can be met; in addition, the low-voltage power supply box can also provide power requirements for monitoring of well sites, fire protection and the like, so that the problems that various boxes are scattered in the well sites, the occupied area is large, and the utilization rate of the land is reduced are solved. In a word, the skid-mounted structure adopted by the utility model saves space, improves the installed capacity of new energy sources in the oilfield well site, further improves the conversion and utilization efficiency of the new energy sources, and provides technical support for efficient development and utilization of the new energy sources in the oilfield.

Drawings

FIG. 1 is a schematic top view of the one-piece skid of the present utility model;

FIG. 2 is a schematic diagram of the front structure of the high voltage inlet cabinet;

FIG. 3 is a perspective view of the high voltage inlet cabinet;

fig. 4 is a schematic diagram of the internal structure of the high-voltage incoming line cabinet;

FIG. 5 is a schematic A-A diagram of the high voltage inlet cabinet;

FIG. 6 is a schematic view of the internal structure of the high-voltage metering cabinet;

FIG. 7 is a schematic diagram of the front structure of the high-voltage metering cabinet;

FIG. 8 is a perspective view of a high voltage metering cabinet;

FIG. 9 is a schematic view of the internal structure of the rectifier cabinet;

FIG. 10 is a schematic view of the B-B structure of FIG. 9;

FIG. 11 is a perspective view of a rectifier cabinet;

FIG. 12 is a schematic view of the structure of the cable gland at the bottom of the rectifier cabinet;

in the upper graph: the skid-mounted house comprises a skid-mounted base (1), a skid-mounted house (2), a vent (3), a high-voltage line inlet (4), a high-voltage line outlet (5), a first low-voltage line outlet (6), a second low-voltage line outlet (7), a reinforcing column (8), a door (9), a high-voltage metering cabinet (1.1), a high-voltage line inlet cabinet (1.2), a high-voltage line outlet cabinet (1.3), a transformer (1.4), a rectifying cabinet (1.5), a first converging cabinet (1.6) and a second converging cabinet (1.7), a low-voltage metering box (1.8), a low-voltage power supply box (1.9), a data acquisition box (1.10), a first energy storage battery (1.11), a second energy storage battery (1.12) and a fan (1.13); high-voltage fuse (1.2.1), current transformer (1.2.2), lightning arrester (1.2.3), combined breaker (1.2.4), voltage transformer (1.2.5), live display (1.2.6), high-voltage protection module (1.2.7), incoming line cabinet main body (1.2.8), heat dissipation module (1.2.9); the measuring cabinet comprises a measuring cabinet main body (1.1.1), a second current transformer (1.1.2), a high-voltage PT, a CT measuring box (1.1.3), radiating holes (1.1.4), radiating plates (1.1.5), a display screen 1.1.6, a rectifying cabinet main body 1.5.1, a rectifying mounting frame 1.5.2, isolating switches 1.5.3, a four-quadrant rectifier 1.5.4, a second circuit breaker 1.5.5, cabinet radiating holes 1.5.6 and a cable grid 1.5.7.

Detailed Description

The preferred embodiments of the present utility model will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present utility model only, and are not intended to limit the present utility model.

Embodiment 1, refer to FIG. 1, the utility model relates to an oilfield well field energy routing cabin, which comprises a skid-mounted base (1), a skid-mounted house (2), a vent (3), a high-voltage wire inlet (4), a high-voltage wire outlet (5), a first low-voltage wire outlet (6), a second low-voltage wire outlet (7), a reinforcing column (8) and a door (9), wherein the skid-mounted house (2) is fixedly mounted on the skid-mounted base (1), the door (9) is arranged on one side of the skid-mounted house (2), the high-voltage wire inlet (4), the high-voltage wire outlet (5), the first low-voltage wire outlet (6), the second low-voltage wire outlet (7) and the vent (3) are arranged around, the skid-mounted house (2) in install a plurality of cuts off, form high-pressure measuring room, transformer room, rectification room and energy storage room, high-pressure measuring room includes high-pressure measuring cabinet (1.1), the output of high-pressure measuring cabinet (1.1) is connected to transformer (1.4) in the transformer room through high-voltage wire, the output of transformer (1.4) is connected to rectifier cabinet (1.5) in the rectification room through the wire, first conflux cabinet (1.6) and second conflux cabinet (1.7) are connected to the output of rectifier cabinet (1.5), still be equipped with low-voltage metering box (1.8), low-voltage power supply box (1.9), data acquisition box (1.10) in the rectification room, a fan (1.13) is arranged at the ventilation opening (3); one side of the transformer room is an energy storage room, and more than one group of energy storage batteries are arranged in the energy storage room.

The energy storage battery comprises a first energy storage battery (1.11) and a second energy storage battery (1.12), and the first energy storage battery and the second energy storage battery are respectively connected to solar cell modules installed at well sites through controllers.

One side of the high-voltage metering cabinet (1.1) is provided with the high-voltage outlet cabinet (1.3), and the output end of the high-voltage outlet cabinet (1.3) is connected to the outer side of the skid-mounted house (2) through the high-voltage outlet (5).

The front end of the high-voltage metering cabinet (1.1) is connected with the high-voltage wire inlet cabinet (1.2) through a high-voltage wire, and the output end of the high-voltage wire inlet cabinet (1.2) is connected with the high-voltage metering cabinet (1.1).

In addition, reinforcing columns (8) which are longitudinally arranged are arranged at four corners of the skid-mounted base (1) and the skid-mounted house (2), so that the strength of the whole skid-mounted house is improved.

Referring to fig. 2-5, the high-voltage incoming cabinet (1.2) comprises a high-voltage fuse (1.2.1), a current transformer (1.2.2), a lightning arrester (1.2.3), a combined circuit breaker (1.2.4), a voltage transformer (1.2.5) and an incoming cabinet main body (1.2.8), wherein the incoming cabinet main body (1.2.8) is of a cuboid structure, the high-voltage fuse (1.2.1) and the combined circuit breaker (1.2.4) are arranged in the middle of an inner cavity of the incoming cabinet main body (1.2.8), and one side of the high-voltage fuse (1.2.1) is connected with the combined circuit breaker (1.2.4); a current transformer (1.2.2) and a voltage transformer (1.2.5) are arranged at the lower side of the inner cavity of the wire inlet cabinet main body (1.2.8); and a lightning arrester (1.2.3) is arranged at the bottom of the inner cavity of the incoming line cabinet main body (1.2.8).

Wherein, electrified display (1.2.6) and high-voltage protection module (1.2.7) are installed on the upper portion side wall of above-mentioned inlet wire cabinet main part (1.2.8), and upper portion rear side of inlet wire cabinet main part (1.2.8) is equipped with heat dissipation module (1.2.9).

Referring to fig. 6-8, the high-voltage metering cabinet (1.1) comprises a metering cabinet main body (1.1.1), a second current transformer (1.1.2), a high-voltage PT, a CT metering box (1.1.3) and radiating holes (1.1.4), wherein the second current transformer (1.1.2) is arranged at the lower part of an inner cavity of the metering cabinet main body (1.1.1), the high-voltage PT and the CT metering box (1.1.3) are arranged below the second current transformer (1.1.2), and a plurality of groups of radiating holes (1.1.4) are arranged on the side wall of the metering cabinet main body (1.1.1).

Wherein, the upper side rear part of the high-voltage metering cabinet (1.1) is provided with a heat radiation plate (1.1.5), and a plurality of heat radiation holes are distributed on the heat radiation plate (1.1.5).

When the novel energy-saving type energy-saving house is used, a plurality of partitions are arranged in the skid-mounted house (2) to form a high-voltage metering chamber, a transformer chamber, a rectifying chamber and an energy storage chamber, a high-voltage metering cabinet (1.1), a high-voltage wire inlet cabinet (1.2), a high-voltage wire outlet cabinet (1.3), a transformer (1.4), a rectifying cabinet (1.5), a first converging cabinet (1.6) and a second converging cabinet (1.7), a low-voltage metering box (1.8), a low-voltage power supply box (1.9), a data collecting box (1.10), a first energy storage battery (1.11) and a second energy storage battery (1.12) are respectively arranged in the skid-mounted house (2), so that the occupied area is compact, management and control are more convenient, and a fan (1.13) is arranged at a ventilation opening (3) on the side wall of the skid-mounted house (2) for facilitating heat dissipation;

during operation, outsourced high-voltage electricity is connected with a high-voltage wire inlet cabinet (1.2) through a high-voltage wire, the output end of the high-voltage wire inlet cabinet (1.2) is connected with a high-voltage metering cabinet (1.1), metering is performed through the high-voltage metering cabinet (1.1), then voltage required by a well site is transformed through a transformer (1.4), and the other parts are connected to the outer side of a skid-mounted house (2) through an output end of the high-voltage wire outlet cabinet (1.3) through a high-voltage wire outlet (5) and then are transported to other well sites in parallel for use; the low voltage transformed by the transformer (1.4) is rectified by the rectifying cabinet (1.5), and then is output to the outside of the well site through the first converging cabinet (1.6) and the second converging cabinet (1.7) for operation; in addition, solar photovoltaic modules distributed on the well site are connected to the first energy storage battery (1.11) and the second energy storage battery (1.12) through the controller for storage, and when the well site is maintained at night or in the well site, the discharging function of the first energy storage battery (1.11) and the discharging function of the second energy storage battery (1.12) are started, so that the operation cost of the well site is reduced through self-power generation, and the power supply requirement during the well site maintenance can be met; in addition, the low-voltage power supply box can also provide power requirements for monitoring of well sites, fire protection and the like, so that the problems that various boxes are scattered in the well sites, the occupied area is large, and the utilization rate of the land is reduced are solved. In a word, the skid-mounted structure adopted by the utility model saves space, improves the installed capacity of new energy sources in the oilfield well site, further improves the conversion and utilization efficiency of the new energy sources, and provides technical support for efficient development and utilization of the new energy sources in the oilfield.

Embodiment 2, the utility model mentions an oilfield well field energy routing cabin, including sled dress base (1), sled dress house (2), vent (3), high-voltage line import (4), high-voltage line export (5), first low-voltage line export (6), second low-voltage line export (7), spliced pole (8), door (9), fixed mounting sled dress house (2) on sled dress base (1), one side of sled dress house (2) is equipped with door (9), is equipped with high-voltage line import (4) all around, high-voltage line export (5), first low-voltage line export (6), second low-voltage line export (7) and vent (3), sled dress house (2) in install a plurality of cuts off, form high-voltage metering chamber, transformer room, rectification room and energy storage room, the high-voltage metering chamber includes high-voltage metering cabinet (1.1), the output of high-voltage metering cabinet (1.1) is connected to transformer (1.4) in the transformer room through high-voltage wire, the output of transformer (1.4) is connected to rectifying cabinet (1.5) in through the wire, still is equipped with rectifying cabinet (1.5), the first junction box (1.1.5), the low-voltage box (1.1) is connected with the power supply box (1.1), a fan (1.13) is arranged at the ventilation opening (3); one side of the transformer room is an energy storage room, and more than one group of energy storage batteries are arranged in the energy storage room.

The difference from example 1 is that:

referring to fig. 9-12, the rectifier cabinet provided by the utility model comprises a rectifier cabinet main body 1.5.1, a rectifier mounting frame 1.5.2, an isolating switch 1.5.3, a four-quadrant rectifier 1.5.4, a second circuit breaker 1.5.5, a cabinet radiating hole 1.5.6 and a cable gram 1.5.7, wherein the rectifier cabinet main body 1.5.1 is of a cuboid structure, the rectifier mounting frame 1.5.2 is arranged in an inner cavity of the rectifier cabinet main body 1.5.1, an isolating switch 1.5.3 is arranged at the upper part of the rectifier mounting frame 1.5.2, the four-quadrant rectifier is arranged in the middle of the rectifier mounting frame 1.5.2, the circuit of a transformer after voltage reduction is rectified, bidirectional energy flow control can be realized, the second circuit breaker 1.5.5 is arranged at the lower side of the rectifier mounting frame 1.5.2, the cable gram 1.5.7 is arranged at the bottom of the rectifier cabinet main body 1.5.1, and the cable gram 1.5.7 is convenient for wire cable wire inlet and outlet.

The above description is of the preferred embodiments of the present utility model, and any person skilled in the art may modify the present utility model or make modifications to the present utility model with the technical solutions described above. Therefore, any simple modification or equivalent made according to the technical solution of the present utility model falls within the scope of the protection claimed by the present utility model.

Claims (9)

1. An oilfield well energy routing cabin, which is characterized in that: the novel high-voltage power supply system comprises a skid-mounted base (1), a skid-mounted house (2), a vent (3), a high-voltage wire inlet (4), a high-voltage wire outlet (5), a first low-voltage wire outlet (6), a second low-voltage wire outlet (7), a reinforcing column (8) and a door (9), wherein the skid-mounted house (2) is fixedly mounted on the skid-mounted base (1), the door (9) is arranged on one side of the skid-mounted house (2), the high-voltage wire inlet (4), the high-voltage wire outlet (5), the first low-voltage wire outlet (6), the second low-voltage wire outlet (7) and the vent (3) are arranged around, a plurality of partitions are mounted in the skid-mounted house (2), a high-voltage metering chamber, a transformer chamber, a rectifying chamber and an energy storage chamber are formed, the high-voltage metering chamber comprises a high-voltage metering cabinet (1.1), the output end of the high-voltage metering chamber is connected to the transformer (1.4) in the transformer chamber through a high-voltage wire, the output end of the transformer (1.4) is connected to the rectifying cabinet (1.5) in the rectifying chamber through the wire, the first rectifying chamber is connected with the first low-voltage metering chamber (1.6), the second rectifying chamber (1.1.5), and the first low-voltage metering chamber (1.7) is connected to the second rectifying chamber (1.1.5), and the second rectifying chamber is further connected to the high-voltage metering chamber (1.1.1.1). One side of the transformer room is an energy storage room, and more than one group of energy storage batteries are arranged in the energy storage room.

2. The oilfield wellsite energy routing capsule of claim 1, wherein: the energy storage battery comprises a first energy storage battery (1.11) and a second energy storage battery (1.12), and the first energy storage battery and the second energy storage battery are respectively connected to solar cell modules installed at well sites through controllers.

3. The oilfield wellsite energy routing capsule of claim 2, wherein: one side of the high-voltage metering cabinet (1.1) is provided with a high-voltage outlet cabinet (1.3), and the output end of the high-voltage outlet cabinet (1.3) is connected to the outer side of the skid-mounted house (2) through a high-voltage outlet (5).

4. An oilfield well energy routing capsule of claim 3, wherein: the front end of the high-voltage metering cabinet (1.1) is connected with the high-voltage wire inlet cabinet (1.2) through a high-voltage wire, and the output end of the high-voltage wire inlet cabinet (1.2) is connected with the high-voltage metering cabinet (1.1).

5. The oilfield wellsite energy routing capsule of claim 4, wherein: the high-voltage incoming cabinet (1.2) comprises a high-voltage fuse (1.2.1), a current transformer (1.2.2), a lightning arrester (1.2.3), a combined circuit breaker (1.2.4), a voltage transformer (1.2.5) and an incoming cabinet main body (1.2.8), wherein the incoming cabinet main body (1.2.8) is of a cuboid structure, the high-voltage fuse (1.2.1) and the combined circuit breaker (1.2.4) are arranged in the middle of an inner cavity of the incoming cabinet main body (1.2.8), and one side of the high-voltage fuse (1.2.1) is connected with the combined circuit breaker (1.2.4); a current transformer (1.2.2) and a voltage transformer (1.2.5) are arranged at the lower side of the inner cavity of the wire inlet cabinet main body (1.2.8); and a lightning arrester (1.2.3) is arranged at the bottom of the inner cavity of the incoming line cabinet main body (1.2.8).

6. The oilfield wellsite energy routing capsule of claim 5, wherein: an electrified display (1.2.6) and a high-voltage protection module (1.2.7) are arranged on the side wall of the upper portion of the incoming line cabinet main body (1.2.8), and a heat dissipation module (1.2.9) is arranged on the rear side of the upper portion of the incoming line cabinet main body (1.2.8).

7. The oilfield wellsite energy routing capsule of claim 6, wherein: the high-voltage metering cabinet (1.1) comprises a metering cabinet main body (1.1.1), a second current transformer (1.1.2), a high-voltage PT, a CT metering box (1.1.3) and radiating holes (1.1.4), the second current transformer (1.1.2) is arranged at the lower part of an inner cavity of the metering cabinet main body (1.1.1), the high-voltage PT and the CT metering box (1.1.3) are arranged below the second current transformer (1.1.2), and a plurality of groups of radiating holes (1.1.4) are formed in the side wall of the metering cabinet main body (1.1.1).

8. The oilfield wellsite energy routing capsule of claim 7, wherein: the rear part of the upper side of the high-voltage metering cabinet (1.1) is provided with a radiating plate (1.1.5), and a plurality of radiating holes are distributed on the radiating plate (1.1.5).

9. The oilfield wellsite energy routing capsule of claim 8, wherein: the rectifier cabinet comprises a rectifier cabinet main body (1.5.1), a rectifier mounting frame (1.5.2), an isolating switch (1.5.3), a four-quadrant rectifier (1.5.4), a second circuit breaker (1.5.5), a cabinet body radiating hole (1.5.6) and cable aglet (1.5.7), wherein the rectifier cabinet main body (1.5.1) is of a cuboid structure, the rectifier mounting frame (1.5.2) is arranged in an inner cavity of the rectifier cabinet main body (1.5.1), the isolating switch (1.5.3) is arranged on the upper portion of the rectifier mounting frame (1.5.2), the four-quadrant rectifier is arranged in the middle of the rectifier mounting frame (1.5.2), the second circuit breaker (1.5.5) is arranged on the lower side of the rectifier mounting frame (1.5.2), the cabinet body radiating hole (1.5.6) is formed in the lower side of the rectifier cabinet main body (1.5.1), and the cable aglet (1.5.7) is arranged at the bottom of the rectifier cabinet main body (1.5.1).