CN217361319U - Integrated traction transformer assembly - Google Patents

Abstract

The application relates to the field of rail transit and electricity, and discloses an integrated form traction transformer assembly, including traction transformer body, pipeline subassembly and cooler, the traction transformer body includes the oil tank, the cooler links firmly the lateral part of oil tank, the cooler with the oil tank passes through pipeline subassembly intercommunication, the pipeline subassembly is equipped with and is used for driving the oil pump of coolant oil circulation. The integrated form traction transformer assembly that this application provided realizes the integrated design, and the volume is showing and is reducing, is convenient for install to rail transit vehicle bottom, utilizes walking wind and cooler to cool off the traction transformer body.

Description

Integrated traction transformer assembly

Technical Field

The application relates to the field of rail transit and electricity, in particular to an integrated traction transformer assembly.

Background

The track traffic vehicle traction transformer is arranged on a train, converts high-voltage electricity of 25kV of a contact network into various low-voltage electricity required by a traction system and an auxiliary system, is a power transformer with a special voltage class, needs to meet the requirement of severe traction load change, and simultaneously needs to suppress harmonic current and limit short-circuit current, so that the safe, stable and reliable operation of an electric transmission system of the train is ensured, and the track traffic vehicle traction transformer is a power source of a track vehicle and is a core and a key component of the traction system.

The existing rail transit vehicle traction transformer usually adopts a cooling mode of forced ventilation of a cooling fan. The transformer has the advantages of higher noise, lower efficiency, driving power consumption of the fan, more maintenance work, and special protection devices and control logics for the train, so as to monitor whether the cooling fan works normally when the train runs. Moreover, such traction transformers occupy a large volume/space, and the installation location is greatly limited.

SUMMERY OF THE UTILITY MODEL

The purpose of this application is to provide an integrated form traction transformer assembly, this integrated form traction transformer assembly realizes the integrated design, and the volume is showing and is reducing, is convenient for install to rail transit vehicle bottom, utilizes walking wind and cooler to cool off the traction transformer body.

In order to achieve the above object, the present application provides an integrated traction transformer assembly, which includes a traction transformer body, a pipeline component and a cooler, wherein the traction transformer body includes an oil tank, the cooler is fixedly connected to a side portion of the oil tank, the cooler and the oil tank are communicated through the pipeline component, and the pipeline component is provided with an oil pump for driving cooling oil to circulate.

In some embodiments, the traction transformer body is provided with a first rib plate fixedly connected with the oil tank and extending towards the outer side of the oil tank, and the cooler is mounted on the first rib plate.

In some embodiments, the coolers are arranged in two groups and symmetrically arranged on two sides of the oil tank, and the oil tank further comprises an oil storage cabinet, a high-voltage outlet wire and a low-voltage outlet wire, wherein the high-voltage outlet wire and the low-voltage outlet wire are arranged on the same side surface adjacent to the side surface where the coolers are arranged.

In some embodiments, the cooler is disposed on one side parallel to the traveling direction, and further includes an oil conservator, a high-voltage outlet line, and a low-voltage outlet line, and at least one of the oil conservator, the high-voltage outlet line, and the low-voltage outlet line is disposed on one side of the oil tank away from the cooler.

In some embodiments, the cooler includes a cooling tube group, a base plate, and an oil box assembly, the cooling tube group includes a plurality of rows of cooling tube bodies bent in a circular arc shape with a predetermined gap, and the cooling tube group is fixed by the base plate and communicates with the oil box assembly.

In some embodiments, the two sets of coolers are arranged in series through a pipeline assembly, the pipeline assembly comprises a first pipeline, a second pipeline, a third pipeline, a built-in oil duct, a fourth pipeline and a fifth pipeline which are sequentially communicated, the built-in oil duct is located inside the traction transformer body, the first pipeline is connected with the upper portion of the oil tank, the oil pump is used for pumping hot oil on the upper portion of the oil tank out through the first pipeline and sending the hot oil to the cooler on one side of the oil tank through the second pipeline, and oil which is primarily cooled by the cooler enters the cooler on the other side of the oil tank after sequentially passing through the third pipeline, the built-in oil duct and the fourth pipeline, so that the oil which is secondarily cooled flows into the oil tank through the fifth pipeline, and cooling of transformer oil is achieved.

In some embodiments, the gap between any adjacent cooling tube bodies is tapered from the inner periphery to the outer periphery, and the cooling tube further comprises a square tube which is arranged in the center of the cooling tube body on the inner periphery and is connected with the base plate and used for turbulent flow.

In some embodiments, the oil box assembly includes a first oil box, a second oil box, and a third oil box, the cooling tube group includes a first cooling tube group provided at a front end and communicating the first oil box and the second oil box, and a second cooling tube group provided at a rear end and communicating the second oil box and the third oil box, and a gap between the first cooling tube group and the second cooling tube group is larger than a gap between the first cooling tube group or the second cooling tube group as compared to the cooling tube body; one end of the pipeline assembly for delivering oil to the cooler is communicated to the first oil box, and the other end of the pipeline assembly for extracting the cooling oil in the cooler is communicated to the third oil box.

In some embodiments, the traction transformer further comprises second rib plates fixedly connected to two sides of the oil tank, the second rib plates are connected with first longitudinal beams, and the first longitudinal beams are welded with pin shafts, so that the traction transformer body is installed on the second longitudinal beams at the bottom of the rail transit through the first longitudinal beams and the pin shafts.

In some embodiments, the second web is recessed toward the fuel tank side.

The utility model provides an integrated form traction transformer assembly sets up the cooler through the both sides at the traction transformer body, utilize oil pump and pipeline subassembly with the hot cooling oil pump sending to the cooler circulative cooling of the oil tank of traction transformer body, make full use of walking wind is to the heat transfer of hot cooling oil in the cooler, and cooler erection joint is at the lateral part of oil tank, very big simplification laying of transformer cooling system, the volume of integrated form traction transformer assembly has been reduced, be convenient for install to rail transit vehicle bottom.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

FIG. 1 is a schematic illustration of an integrated traction transformer assembly according to an embodiment of the present application;

FIG. 2 is a front view of FIG. 1;

FIG. 3 is a rear view of FIG. 1;

FIG. 4 is a schematic view of a first web;

FIG. 5 is a schematic view of a second web;

FIG. 6 is a schematic cross-sectional view of a fuel tank;

FIG. 7 is an angled assembly view of a cooler provided in accordance with an embodiment of the present application;

FIG. 8 is an assembly view of another angle of a cooler provided in accordance with an embodiment of the present application;

FIG. 9 is a top view of FIG. 7;

FIG. 10 is a schematic view of a shield;

FIG. 11 is an internal schematic view of a cooling tube body;

fig. 12 is a schematic view illustrating an installation of an integrated traction transformer assembly according to still another embodiment of the present application.

Wherein:

01-transformer body, 1-traction transformer body, 2-first pipeline, 3-oil pump, 4-second pipeline, 5-first rib plate, 6-second rib plate, 7-front end equipment, 8-third pipeline, 9-high-voltage outgoing line, 10-low-voltage outgoing line, 11-fourth pipeline, 12-pin shaft, 13-second longitudinal beam, 14-first longitudinal beam, 15-fifth pipeline, 16-rear end equipment, 17-radiating fin, 18-built-in oil duct, 19-vehicle bottom limit, 20-cooler, 21-damping pad, 22-oil tank, 23-winding, 24-oil conservator, 25-stop block, 26-protective cover, 27-cooling pipe group, 271-first cooling pipe group, 272-second cooling pipe group, 28-cooling tube body, 281-reinforcing rib, 29-square tube, 30-reinforcing plate, 31-base plate, 32-first oil box, 33-second oil box and 34-third oil box.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In order to better understand the technical scheme of the present application, the following detailed description is provided for the person skilled in the art with reference to the accompanying drawings and the detailed description.

The application provides an integrated form traction transformer assembly, with cooler 20 integration in the lateral part of traction transformer body 1, usable oil pump 3 and pipeline subassembly realize that the coolant oil circulates between traction transformer body 1 and cooler 20 simultaneously, cool off traction transformer body 1. The arrangement obviously reduces the volume of the integrated traction transformer assembly, the integrated traction transformer assembly is convenient to be arranged at the bottom of a rail transit vehicle and keeps a set distance with the front-end equipment 7 and the rear-end equipment 16, the integrated traction transformer assembly is cooled by utilizing a complicated flow field at the bottom of the vehicle and running wind, and the operation and maintenance cost is reduced.

In an embodiment provided by the present application, referring to fig. 1 to 5, the direction of the arrow in fig. 1 is a driving direction, and the traction transformer body 1 includes a winding 23, a tank 22, a high voltage outlet 9, a low voltage outlet 10, and the like. Two opposite sides extend to the outside about oil tank 22 and set up first gusset 5, and the first gusset 5 of each side specifically sets up two sets ofly, and two sets of first gussets 5 of oil tank 22 unilateral are located the front end and the rear end of oil tank 22 respectively, and the lower extreme setting of first gusset 5 is close the rectangle, and one side is vertical to be seted up one row of mounting hole far away from oil tank 22 to first gusset 5, and cooler 20 passes through the mounting hole and is connected fixedly with first gusset 5. And a hole position for the oil supply pipe assembly to penetrate and fix is formed below the first rib plate 5.

The pair of second rib plates 6 are further arranged on the outer side of the oil tank 22 of the traction transformer body 1, and the second rib plates 6 are concavely arranged towards the oil tank 22, so that the second rib plates are avoided from the cooler 20 as far as possible, and the heat exchange area of the cooler 20 is increased. The end of the second rib 6 remote from the oil tank 22 is fixedly connected with a first longitudinal beam 14, the outer side of the first longitudinal beam 14 is vertically connected with a pin shaft 12, so that a second longitudinal beam 13 arranged in the running direction within the range of the vehicle bottom limit 19 is arranged at the bottom of the vehicle, and the integrated traction transformer assembly is arranged at the bottom of the vehicle by means of the second longitudinal beam 13, the pin shaft 12, the first longitudinal beam 14 and the second rib 6. The pin 12 can be connected with the second longitudinal beam 13 through a damping pad 21, so that the vibration caused by the magnetostriction of the iron core when the transformer operates can be isolated. To vehicle bottom limit 19, vehicle bottom limit 19 is used for connecting in the bottom of carriage, and vehicle bottom limit 19's top is wide, and the bottom is narrow, and both sides face from upper and lower slope to carriage central authorities extend, and both sides face sets up to the arc, fully with the adaptation of 20 laminatings of cooler, when conveniently passing through the tunnel, balanced lateral part air current reduces the driving lateral part resistance, improves the cooling efficiency of cooler 20.

In this embodiment, the high-voltage outgoing line 9 and the low-voltage outgoing line 10 are both disposed on the same side surface adjacent to the side surface where the cooler 20 is located, that is, on the side adjacent to the side surface where the cooler 20 is mounted as shown in fig. 1, so as to reduce the size of the traction transformer body 1 in the traveling direction; the oil conservator 24 can be disposed on top of the oil tank 22, and can be disposed at other positions according to actual needs, which is not limited herein. The oil conservator 24 is communicated with the oil tank 22 through a pipeline, when the temperature in the transformer is increased, the oil volume in the oil tank 22 expands and flows to the oil conservator 24, and when the temperature in the transformer is reduced, the oil volume in the oil tank 22 is reduced, and the oil in the oil conservator 24 flows into the oil tank 22 for compensation. In particular implementation, both the high-voltage outlet line 9 and the low-voltage outlet line 10 and the conservator 24 may also be divided, with reference to fig. 12, on a pair of sides of the tank 22 adjacent to the side on which the cooler 20 is located. The oil tank 22 is connected with the cooler 20 through a pipeline assembly and the oil pump 3, and hot cooling oil is pumped out of the oil tank 22 through the oil pump 3, sent to the cooler 20 and then returned to the oil tank 22 after being cooled.

In an embodiment, the traction transformer body 1, that is, the bottom of the oil tank 22, is provided with a plurality of rows of cooling fins 17, and the cooling fins 17 penetrate through the whole bottom of the oil tank 22, so as to increase the bottom cooling area. The fins 17 are arranged at equal intervals. When the integrated traction transformer assembly is installed at the bottom of a rail transit vehicle, each row of radiating fins 17 are parallel to the traveling direction, and the resistance of the traveling wind is reduced. The bottom of the radiating fin 17 does not exceed the vehicle bottom limit 19, and the high-flow-speed running wind at the bottom of the vehicle is fully utilized for heat dissipation, so that the heat dissipation capacity of the transformer is improved.

Certainly, in the specific implementation, the heat dissipation fins 17 may also be disposed at unequal intervals, and the heat dissipation fins 17 may be directly welded to the bottom of the oil tank 22, or may be welded to a heat dissipation plate and then connected to the bottom of the oil tank 22.

In the above embodiment, taking the two groups of coolers 20 as an example, which are respectively fixedly connected to two sides of the oil tank 22, the pipeline assembly includes the first pipeline 2, the second pipeline 4, the third pipeline 8, the fourth pipeline 11, the fifth pipeline 15 and the built-in oil duct 18, the first pipeline 2 is connected to the upper portion of the oil tank 22, the oil pump 3 pumps hot oil at the upper portion of the transformer oil tank 22 through the first pipeline 2, and sends the hot oil to the cooler 20 located on one side of the oil tank 22 through the second pipeline 4, oil primarily cooled by the cooler 20 located on one side of the oil tank 22 passes through the third pipeline 8, the built-in oil duct 18 and the fourth pipeline 11 and then enters the cooler 20 on the other side of the oil tank 22, and oil secondarily cooled by the cooler 20 located on the other side of the oil tank 22 flows into the oil tank 22 through the fifth pipeline 15, so as to cool the transformer oil.

That is, the first pipeline 2, the oil pump 3, the second pipeline 4, the cooler 20 at one side of the oil tank 22, the third pipeline 8, the built-in oil passage 18, the fourth pipeline 11, the cooler 20 at the other side of the oil tank 22 and the fifth pipeline 15 jointly form a series oil passage, and meanwhile, the built-in oil passage 18 is adopted, so that the arrangement of the oil passage is simplified, the size of the integrated traction transformer assembly along the driving direction is reduced, and the installation space of equipment under the vehicle is saved; meanwhile, the arrangement mode of the built-in oil duct 18 is adopted, so that the arrangement of oil ducts is simplified, the driving direction sizes of a cooling system and the transformer are reduced, the overall weight of the transformer is reduced, and the installation space of equipment under the vehicle is saved.

Besides, the internal oil passage 18 can be replaced by an external pipeline, the external pipeline is arranged on the outer side of the oil tank 22, and two ends of the external pipeline are respectively communicated with the third pipeline 8 and the fourth pipeline 11, so that the communication of the oil passages is realized.

Referring to fig. 6, the internal oil passage 18 is disposed inside the oil tank 22, the oil tank 22 and the transformer body 01 are disposed closely, the cross section of the internal oil passage 18 is triangular, and the internal oil passage 18 is perpendicular to the traveling direction and penetrates through the inside of the whole transformer. Because the transformer winding is circular, and has a relatively large space at the corner with the oil tank 22, the built-in oil passage 18 makes full use of the space at the corner, avoids the situation that an independent oil pipe is arranged outside the oil tank 22 to occupy extra space, and is beneficial to the miniaturization, the light weight and the simple design of the transformer. Of course, the internal oil passage 18 may also be provided in other conformal shapes in cross section, and will not be expanded herein.

Further, the two coolers 20 can be both arranged in a circular arc shape, and both the two coolers are matched with the bottom limit 19 of the vehicle, and meanwhile, the two coolers 20 are respectively close to two sides of the bottom limit 19, so that the space of the vehicle body can be fully utilized, the two coolers 20 are prevented from occupying too much space, and the heat dissipation effect of the two coolers 20 is improved.

In an embodiment, a group of coolers 20 may be further provided, one group of coolers 20 is provided on one side of the direction parallel to the traveling direction of the oil tank 22 through the first rib plate 5, at least one of the high-voltage outgoing line 9, the low-voltage outgoing line 10 and the oil conservator 24, such as the low-voltage outgoing line 10, is provided on the opposite side of the oil tank 22 where the cooler 20 is located, and correspondingly, the high-voltage outgoing line 9 and the oil conservator 24 may be respectively provided on the adjacent sides of the side of the oil tank 22 where the cooler 20 is located.

Referring to fig. 7 to 11, in an integrated traction transformer assembly according to an embodiment of the present application, a cooler 20 mainly includes a cooling tube set 27, a base plate 31 and an oil box assembly, and the cooling tube set 27 is fixed to the base plate 31 and is communicated with the oil box assembly through the base plate 31. In this embodiment, the oil box assembly includes a first oil box 32, a second oil box 33, and a third oil box 34, i.e., has three cavities. The cooling pipe group 27 comprises a plurality of rows of cooling pipe bodies 28 bent into an arc shape at preset gaps, the cooling pipe bodies 28 in each row are arranged in a coplanar manner, and the plane of the cooling pipe body 28 in each row is vertical to the travelling direction, so that the cooling pipe group 27 forms a plurality of channels parallel to the travelling direction, and travelling wind can pass through the channels; of course, in practical implementation, the cooling tube bodies 28 of each row may be arranged in a staggered manner, not in a plane, and the application is not limited thereto.

The plurality of reinforcing plates 30 are disposed between the cooling tube main bodies 28, and the plurality of reinforcing plates 30 are arranged in parallel to the traveling direction and in a direction perpendicular to the traveling direction, so that the overall strength of the cooling tube group 27 can be increased and large vibration can be prevented from occurring during operation.

The cooling tube group 27 further includes a first cooling tube group 271 composed of a plurality of cooling tube bodies 28 at the front end in the traveling direction and a second cooling tube group 272 composed of a plurality of cooling tube bodies 28 at the rear end in the traveling direction, depending on the connections with the different oil tanks. The clearance between the first cooling tube group 271 and the second cooling tube group 272 is larger than the clearance of the cooling tube bodies 28 of the first cooling tube group 271 or the second cooling tube group 272, and the wind resistance of the traveling wind entering the second cooling tube group 272 is reduced; of course, in practical implementation, the gap between the first cooling tube bank 231 and the second cooling tube bank 232 may also be equal to the gap between the first cooling tube bank 231 and the second cooling tube bank 232 for cooling the tube body 24, which is not limited in this application. The pipe assembly conveys the hot cooling oil from the oil tank 22 to the first oil box 32, the first oil box 32 is conveyed to the second oil box 33 through the first cooling pipe group 271 on the periphery, the hot cooling oil is uniformly mixed in the second oil box 33, flows into the third oil box 34 through the second cooling pipe group 272, and is conveyed to the other cooler 20 from the third oil box 34 and the pipe assembly.

The cooling tube body 28 may be a circular tube, a flat tube, an elliptical tube, etc., and is not limited herein. The gaps between the cooling pipe bodies 28 are gradually reduced from the inner periphery to the outer periphery, that is, the gaps between the rows of the cooling pipe bodies 28 on the inner periphery are larger, so that when the train travels, the hot air inside the cooler 20 and the cold air outside the cooler are fully exchanged and mixed in the middle of the cooling pipe group 27, and the improvement of the cooling power of the rear-end cooling pipe group is facilitated. Of course, in practical implementation, the cooling tube bodies 28 may also be disposed at equal intervals, which is not limited in this application.

In one embodiment, the central portion of the cooling tube group 27, i.e. the innermost cooling tube body 28, is further provided with a square tube 29 connected to the base plate 31, so as to disturb the middle traveling wind, increase the heat transfer effect of the cooling tube group 27, and increase the cooling power. The outside of the cooler 20 is provided with a grille-shaped protective cover 26 to prevent foreign matters such as stones under the vehicle from striking the cooler 20, the periphery of the protective cover is provided with folded edges, holes are formed in the folded edges, and bolts penetrate through the holes in the folded edges to connect the protective cover 26 with the substrate 31. The grid ribs of the protective cover 26 at the inlet and the outlet of the traveling wind are thin, the cross sections of the ribs are small, the size of the ribs along the traveling direction is long, and the strength of the grid is increased while the resistance of the traveling wind is reduced; meanwhile, the grid ribs at the bottom of the protective cover 26 close to the ground are more dense, the space between the grid ribs is increased along the upward direction, namely the grid holes below the protective cover 26 are smaller in size so as to increase the protective effect, and the grid holes above the protective cover are larger in size so as to reduce the resistance of the traveling wind entering the cooler 20; the protection effect on the cooler 20 and the reduction of the wind resistance are both considered.

Stoppers 25 are provided above the coolers 20 on both sides to compensate for a gap between the cooler 20 and the vehicle underbody 19, prevent the wind inside the cooler 20 from entering the gap, increase the amount of wind entering the inside of the cooler 20, and increase the heat radiation area. The cooling tube body 28 is further provided with a reinforcing rib 281 as shown in fig. 11, the oil flow is disturbed by the reinforcing rib 281, the heat transfer effect is increased, meanwhile, the heat dissipation area of the oil side can be increased, the heat dissipation power is improved, and the miniaturization and light weight design of the transformer and the cooler 20 is facilitated.

It is noted that, in this specification, relational terms such as first and second, and the like are used solely to distinguish one entity from another entity without necessarily requiring or implying any actual such relationship or order between such entities.

The integrated traction transformer assembly provided by the present application is described in detail above. The principles and embodiments of the present application are explained herein using specific examples, which are provided only to help understand the method and the core idea of the present application. It should be noted that, for those skilled in the art, it is possible to make several improvements and modifications to the present application without departing from the principle of the present application, and such improvements and modifications also fall within the scope of the claims of the present application.

Claims (10)

1. The integrated traction transformer assembly is characterized by comprising a traction transformer body, a pipeline assembly and a cooler, wherein the traction transformer body comprises an oil tank, the cooler is fixedly connected with the side part of the oil tank, the cooler is communicated with the oil tank through the pipeline assembly, and the pipeline assembly is provided with an oil pump for driving cooling oil to circulate.

2. The integrated traction transformer assembly according to claim 1, wherein the traction transformer body is provided with a first rib plate fixedly connected to the oil tank and extending to the outside of the oil tank, and the cooler is mounted to the first rib plate.

3. The integrated traction transformer assembly according to claim 2, wherein the coolers are arranged in two groups and symmetrically arranged on two sides of the oil tank, and further comprising an oil conservator, a high voltage outlet and a low voltage outlet, wherein the high voltage outlet and the low voltage outlet are both arranged on the same side surface adjacent to the side surface where the coolers are arranged.

4. The integrated traction transformer assembly according to claim 2, wherein the cooler is disposed on a side parallel to a traveling direction, and further comprises a conservator, a high voltage outlet, and a low voltage outlet, wherein at least one of the conservator, the high voltage outlet, and the low voltage outlet is disposed on a side of the oil tank away from the cooler.

5. The integrated traction transformer assembly according to any one of claims 2 to 4, wherein the cooler comprises a cooling tube group, a base plate and an oil box component, the cooling tube group comprises a plurality of rows of cooling tube bodies bent in a circular arc shape with a predetermined gap, and the cooling tube group is fixed by the base plate and communicated with the oil box component.

6. The integrated traction transformer assembly according to claim 3, wherein two sets of the coolers are arranged in series through the pipeline assembly, the pipeline assembly comprises a first pipeline, a second pipeline, a third pipeline, a built-in oil passage, a fourth pipeline and a fifth pipeline which are sequentially communicated, the built-in oil passage is located inside the traction transformer body, the first pipeline is connected with the upper portion of the oil tank, the oil pump is used for pumping hot oil at the upper portion of the oil tank out through the first pipeline and sending the hot oil to the cooler located on one side of the oil tank through the second pipeline, oil which is primarily cooled by the cooler passes through the third pipeline, the built-in oil passage and the fourth pipeline in sequence and then enters the cooler located on the other side of the oil tank, so that oil which is secondarily cooled flows into the oil tank through the fifth pipeline, cooling of the oil is achieved.

7. The integrated traction transformer assembly according to claim 5, wherein the gap between any adjacent cooling tube bodies is tapered from the inner periphery to the outer periphery, further comprising a square tube connecting the base plate and serving to disturb the flow, and disposed at the center of the cooling tube body at the inner periphery.

8. The integrated traction transformer assembly according to claim 5, wherein the oil tank assembly comprises a first oil tank, a second oil tank, and a third oil tank, the cooling tube set comprises a first cooling tube set disposed at a front end and communicating the first oil tank and the second oil tank, and a second cooling tube set disposed at a rear end and communicating the second oil tank and the third oil tank, and a gap between the first cooling tube set and the second cooling tube set is larger than a gap between the first cooling tube set or the second cooling tube set compared to the cooling tube body; one end of the pipeline assembly, which is used for pumping the cooling oil in the cooler, is communicated to the third oil box.

9. The integrated traction transformer assembly according to claim 1, further comprising second rib plates fixedly connected to two sides of the oil tank, wherein the second rib plates are connected with first longitudinal beams, and the first longitudinal beams are welded with pins, so that the traction transformer body is mounted on the second longitudinal beams at the bottom of the rail transit through the first longitudinal beams and the pins.

10. The integrated traction transformer assembly according to claim 9, wherein the second rib is recessed toward the oil tank.

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