CN214539972U - Distribution transformer testing platform - Google Patents

Abstract

The utility model discloses a distribution transformer detection platform, which comprises a movable platform, a detection device, a control device and an automatic switching line device; the automatic switching line device comprises a plurality of wiring ends, wiring ports on the outer surface of a carriage of the movable platform correspond to the wiring ends one by one, the wiring ports are used for connecting transformers to be tested, and the automatic switching line device is used for connecting or disconnecting at least part of the wiring ends with the corresponding wiring ports under the control of the control device; the detection device is used for detecting the delivery parameters of the transformer to be detected under the control of the control device; the movable platform is used for driving the distribution transformer detection platform to move horizontally or lift. The utility model discloses a can be at the nimble inspection instrument that removes of scene to and can the automatic control inspection instrument and the technological effect of the break-make between the transformer that awaits measuring, not only improved work efficiency, simplified the detection flow, still reduced inspection cost and human cost.

Description

Distribution transformer testing platform

Technical Field

The embodiment of the utility model provides a relate to transformer detection technical field, especially relate to a distribution transformer testing platform.

Background

When the distribution transformer is subjected to factory inspection at the present stage, different instruments are generally connected with the distribution transformer respectively to inspect the distribution transformer, and different detection instruments need to be connected manually in the inspection process, so that the inspection process is complicated, and labor is consumed; and if the test sample with larger volume or heavier weight is encountered, for example, the test sample which is large and difficult to transport such as a box-type substation, a plurality of inspection instruments are required to be transported to a test site for inspection, so that the working efficiency is low, and the inspection cost is higher.

SUMMERY OF THE UTILITY MODEL

The utility model provides a distribution transformer testing platform has solved among the prior art need carry multiple detecting instrument to the work efficiency who leads to on-the-spot low, the inspection cost is higher when detecting the transformer to and need the manual work to carry out the detection flow that the wiring leads to multiple detecting instrument loaded down with trivial details, consume the technical problem of human cost.

The embodiment of the utility model provides a distribution transformer detection platform, distribution transformer detection platform includes portable platform, detection device, controlling means and automatic switching wire device;

the movable platform is a box-type vehicle body, and the detection device, the control device and the automatic switching line device are all arranged in a carriage of the movable platform; the detection device and the automatic switching line device are electrically connected with the control device;

the automatic switching line device comprises a plurality of wiring ends, wiring ports on the outer surface of a carriage of the movable platform correspond to the wiring ends one by one, the wiring ports are used for connecting transformers to be tested, and the automatic switching line device is used for connecting or disconnecting at least part of the wiring ends with the corresponding wiring ports under the control of the control device;

the detection device is used for detecting the delivery parameters of the transformer to be detected under the control of the control device;

the movable platform is used for driving the distribution transformer detection platform to move horizontally or lift.

Further, the automatic line switching device comprises a high-voltage side automatic line switching sub-device and a low-voltage side automatic line switching sub-device;

the high-voltage side automatic switching wire sub-device comprises a plurality of high-voltage wiring terminals and a first driving module, wherein the first driving module is used for driving the high-voltage wiring terminals to be connected with or disconnected from the corresponding wiring ports;

the low-voltage side automatic switching wire sub-device comprises a plurality of low-voltage terminals and a second driving module, wherein the second driving module is used for driving the low-voltage terminals to be connected with or disconnected from the corresponding wiring ports.

Furthermore, the high-voltage side automatic wire switching sub-device also comprises a plum blossom contact mounting plate and a rack;

each high-voltage terminal comprises a static contact and a plum blossom contact which is arranged corresponding to the static contact; the first driving module comprises at least one electric push rod;

the static contact is electrically connected with the high-voltage side of the transformer to be tested through an outgoing line contact; the fixed contact is arranged on one side, close to the tulip contact, of the top plate of the rack, the outgoing line contact points are arranged on one side, far away from the fixed contact, of the top plate of the rack, and one outgoing line contact point is arranged corresponding to one fixed contact point;

the plum blossom contact is electrically connected with the control device through an incoming line contact; the tulip contacts are arranged on one side of the tulip contact mounting plate, the wire inlet contact points are arranged on one side, far away from the tulip contacts, of the tulip contact mounting plate, and one wire inlet contact point is arranged corresponding to one tulip contact;

the electric push rod is arranged on a side plate of the rack and used for pushing the tulip contact to be communicated with the static contact under the control of the control device.

Furthermore, the static contact comprises a first conduction structure and a second conduction structure, the first conduction structure wraps the second conduction structure, and the first conduction structure and the second conduction structure are insulated;

when the stationary contact is communicated with the plum blossom contact, the first conduction structure is used for transmitting a current signal, and the second conduction structure is used for transmitting a voltage signal.

Further, the device also comprises a high-voltage test device and a movable sliding table;

the high-voltage test device is fixed on the movable sliding table, the movable sliding table is arranged in a carriage of the movable platform, and the movable sliding table is electrically connected with the control device;

the movable sliding table is used for sliding the high-voltage test device out of the carriage of the movable platform under the control of the control device;

the high-voltage test device is used for carrying out a voltage withstand test on the transformer to be tested.

Furthermore, the movable platform comprises a visible liquid crystal rearview mirror, at least two ultrasonic radars, a reversing image camera and a warning lamp;

the visible liquid crystal rearview mirror, the reversing image camera, the ultrasonic radar and the warning lamp are all arranged on the outer side of the carriage of the movable platform; the image camera of backing a car with the ultrasonic radar all set up in the trailing flank of movable platform, just the image camera of backing a car set up in the upper portion intermediate position of trailing flank, at least two the ultrasonic radar set up respectively in both sides about the trailing flank, wherein, the trailing flank points to the direction of advance that the leading flank is movable platform.

Furthermore, the system also comprises a wiring prompt screen; the wiring prompt screen set up in the railway carriage outside of movable platform, just the wiring prompt screen set up in movable platform has the railway carriage surface of wiring mouth one side.

Further, the device also comprises an electrical test operation panel;

the electrical test operation panel is arranged on the outer side of the carriage of the movable platform.

Further, the device also comprises a touch display screen; the touch display screen is fixed on the outer side of the carriage of the movable platform through a turnover structure.

Further, the device also comprises a plurality of fans; the fan is arranged on the top of the carriage of the movable platform.

The utility model discloses a distribution transformer detection platform, which comprises a movable platform, a detection device, a control device and an automatic switching line device; the movable platform is a box-type vehicle body, and the detection device, the control device and the automatic switching line device are all arranged in a carriage of the movable platform; the automatic switching line device comprises a plurality of wiring ends, wiring ports on the outer surface of a carriage of the movable platform correspond to the wiring ends one by one, the wiring ports are used for connecting transformers to be tested, and the automatic switching line device is used for connecting or disconnecting at least part of the wiring ends with the corresponding wiring ports under the control of the control device; the detection device is used for detecting the delivery parameters of the transformer to be detected under the control of the control device; the movable platform is used for driving the distribution transformer detection platform to move horizontally or lift. The utility model provides a need carry the work efficiency that multiple detecting instrument leads to the scene low when detecting the transformer among the prior art, the inspection cost is higher, and need the manual work to carry out the detection flow that the wiring leads to multiple detecting instrument loaded down with trivial details, consume the technical problem of human cost, the inspection instrument can be removed in scene flexibility has been realized, and can the automatic control inspect the technical effect of the break-make between instrument and the transformer that awaits measuring, not only improve work efficiency, the detection flow has been simplified, inspection cost and human cost have still been reduced.

Drawings

Fig. 1 is a structural diagram of a distribution transformer testing platform according to an embodiment of the present invention;

fig. 2 is an external view of a distribution transformer testing platform according to an embodiment of the present invention;

fig. 3 is a left side view of a distribution transformer testing platform according to an embodiment of the present invention;

fig. 4 is a structural diagram of an automatic line switching device according to an embodiment of the present invention;

fig. 5 is a schematic view illustrating a high-voltage side automatic line switching device according to an embodiment of the present invention connected to a movable platform;

fig. 6 is a structural diagram of the high-voltage side automatic wire switching device according to the embodiment of the present invention;

fig. 7 is a rear side view of a distribution transformer testing platform according to an embodiment of the present invention;

fig. 8 is a right side view of a distribution transformer testing platform according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

It should be noted that the terms "first", "second", and the like in the description and claims of the present invention and the accompanying drawings are used for distinguishing different objects, and are not intended to limit a specific order. The embodiments of the present invention can be implemented individually, and can be implemented by combining each other between the embodiments, and the embodiments of the present invention are not limited to this.

Fig. 1 is a structural diagram of a distribution transformer testing platform provided by an embodiment of the present invention.

As shown in fig. 1, the distribution transformer detection platform comprises a movable platform 10, a detection device 20, a control device 30 and an automatic switching line device 40; the movable platform 10 is a box-type vehicle body, and the detection device 20, the control device 30 and the automatic switching line device 40 are all arranged in a carriage of the movable platform 10; the detection device 20 and the automatic switching line device 40 are both electrically connected to the control device 30.

The automatic switching line device 40 includes a plurality of terminals 41, the wiring ports 101 on the outer surface of the carriage of the movable platform 10 correspond to the terminals 41 one by one, the wiring ports 101 are used for connecting the transformer 50 to be tested, and the automatic switching line device 40 is used for connecting or disconnecting at least part of the terminals 41 with the corresponding wiring ports 101 under the control of the control device 30.

The detection device 20 is used for detecting the delivery parameters of the transformer 50 to be detected under the control of the control device 30; the movable platform 10 is used for driving the distribution transformer detection platform to move horizontally or move up and down.

Specifically, the movable platform 10 is a box-type vehicle body, and an electric device capable of lifting and moving is arranged at the bottom of the box-type vehicle body, so that the movable platform 10 can move flexibly. Distribution transformer testing platform make full use of movable platform 10 inside limited space carries out reasonable layout, highly integrates detection device 20, controlling means 30 and automatic switch-over line device 40 in movable platform 10's railway carriage for distribution transformer testing platform's volume compares in traditional transformer testing device's volume, has reduced more than half.

Fig. 2 is an appearance diagram of a distribution transformer testing platform provided by the embodiment of the present invention. Fig. 3 is a left side view of a distribution transformer testing platform provided by an embodiment of the present invention. Illustratively, referring to fig. 2, the distribution transformer test platform may be sized to: 2500mm long, 1050mm wide and 1530mm high.

Illustratively, as shown in fig. 2 and 3, three wiring ports 101 connected to the high-voltage side of the transformer 50 to be tested and four wiring ports 101 connected to the low-voltage side of the transformer 50 to be tested are provided on the outer surface of the carriage of the movable platform 10, the plurality of wiring ports 101 respectively correspond to the wiring terminals 41 of the automatic switching line device 40 provided inside the carriage one by one, a worker can connect one end of a connection line to the wiring ports 101 at one time, and the other end of the connection line is correspondingly connected to the high-voltage side or the low-voltage side of the transformer 50 to be tested, the automatic switching line device 40 is controlled by the control device 20 during the inspection process to realize connection or disconnection with the transformer 50 to be tested, including the high-voltage side automatic switching line, the low-voltage side automatic switching line, the automatic short-circuit line and the like, so that manual line switching is not needed during the inspection process, labor cost is saved, and work efficiency is improved, The detection process is simplified.

For example, the control device 30 may be a single chip microcomputer, and for the detection device 20, multiple types of detection modules may be integrated as needed to meet the factory detection requirement on the transformer, and specifically, the detection items may be as shown in table 1. Each detection module in the detection device 20 is integrated inside the carriage of the movable platform 10, and when any module fails, the module is quickly replaced in a pluggable manner, so that the normal operation of the equipment is ensured.

TABLE 1 detection item table of distribution transformer detection platform

The utility model provides a need carry the work efficiency that multiple detecting instrument leads to the scene low when detecting the transformer among the prior art, the inspection cost is higher, and need the manual work to carry out the detection flow that the wiring leads to multiple detecting instrument loaded down with trivial details, consume the technical problem of human cost, the inspection instrument can be removed in scene flexibility has been realized, and can the automatic control inspect the technical effect of the break-make between instrument and the transformer that awaits measuring, not only improve work efficiency, the detection flow has been simplified, inspection cost and human cost have still been reduced.

Fig. 4 is a structural diagram of an automatic switching line device according to an embodiment of the present invention. Fig. 5 is a schematic diagram of the high-voltage side automatic line switching device according to an embodiment of the present invention connected to a movable platform.

Alternatively, as shown in fig. 4 and 5, the automatic switching line device 40 includes a high-side automatic switching line sub-device 401 and a low-side automatic switching line sub-device 402; the high-voltage side automatic switching line sub-device 401 comprises a plurality of high-voltage terminals 4011 and a first driving module 4012, wherein the first driving module 4012 is used for driving the high-voltage terminals 4011 to be connected with or disconnected from corresponding wiring ports 101; the low voltage side automatic switching line sub-device 402 includes a plurality of low voltage terminals 4021 and a second drive module 4022, and the second drive module 4022 is configured to drive the low voltage terminals 4021 to connect to or disconnect from corresponding connection ports 101.

Specifically, referring to fig. 4 and 5, the high-voltage terminal 4011 is connected to the high-voltage side of the transformer 50 to be tested through the connection port 101 on the external surface of the carriage of the movable platform 10, and similarly, the low-voltage terminal 4021 is connected to the low-voltage side of the transformer 50 to be tested through the connection port 101 on the external surface of the carriage of the movable platform 10, so that the connection between the distribution transformer detection platform and the transformer 50 to be tested is realized. The first drive module 4012 and the second drive module 4022 respectively control the connection and disconnection between the high-voltage terminal 4011 and the low-voltage terminal 4021 and the transformer 50 to be tested under the control of the control device 30, so that automatic line switching between the first drive module 4012 and the transformer 50 to be tested is realized in the inspection process.

Note that the terminals 41 shown in fig. 1 include a high voltage terminal 4011 and a low voltage terminal 4021, and are not described in detail here.

Fig. 6 is a structural diagram of the high-voltage side automatic wire switching device according to the embodiment of the present invention.

Optionally, as shown in fig. 6, the high-voltage side automatic switching line sub-device 401 further includes a tulip contact mounting plate 1 and a frame 2; each high-voltage terminal 4011 comprises a fixed contact 3 and a tulip contact 4 which is arranged corresponding to the fixed contact 3; the first drive module 4012 comprises at least one electric push rod 5.

The static contact 3 is electrically connected with the high-voltage side of the transformer 50 to be tested through the outgoing line contact 6; the fixed contact 3 is arranged on one side, close to the tulip contact 4, of a top plate 21 of the rack 2, the outgoing line contact 6 is arranged on one side, far away from the fixed contact 3, of the top plate 21 of the rack 2, and one outgoing line contact 6 is arranged corresponding to one fixed contact 3.

The tulip contact 4 is electrically connected with the control device 30 through the incoming line contact 7; plum blossom contact 4 sets up in one side of plum blossom contact mounting panel 1, and inlet wire contact 7 sets up in one side that plum blossom contact mounting panel 1 kept away from plum blossom contact 4, and an inlet wire contact 7 and a plum blossom contact 4 correspond the setting.

The electric push rod 5 is arranged on the side plate 22 of the frame 2 and used for pushing the tulip contact 4 to be communicated with the stationary contact 3 under the control of the control device 30.

Specifically, referring to fig. 5 and 6, for the high-voltage side automatic switching line sub-device 401, after the control device 30 receives a connection signal sent by a human-computer interaction unit such as the touch display screen 100 disposed outside the carriage of the movable platform 10, the control device sends a control signal to the first driving module 4012 according to the received connection signal, and after receiving the control signal, the first driving module 4012 controls the electric push rod 5 to push the tulip contact 4 upward, so that the tulip contact 4 is connected to the stationary contact 3, and the connection with the high-voltage side of the transformer 50 to be tested is achieved.

Optionally, as shown in fig. 6, the stationary contact 3 includes a first conducting structure 31 and a second conducting structure 32, the first conducting structure 31 wraps the second conducting structure 2, and the first conducting structure 31 is insulated from the second conducting structure 32; when the stationary contact 3 is communicated with the tulip contact 4, the first conducting structure 31 is used for transmitting a current signal, and the second conducting structure 32 is used for transmitting a voltage signal.

Specifically, the stationary contact 3 is a specially-made communication device, referring to fig. 6, the stationary contact 3 is divided into two parts, namely a first conduction structure 31 and a second conduction structure 32, after the stationary contact 3 is connected with the tulip contact 4, the distribution transformer detection platform collects relevant data of the high-voltage side of the transformer 50 to be detected, and since the first conduction structure can transmit a current signal and the second conduction structure 32 can transmit a voltage signal, different data can be collected at the same time and sent to the distribution transformer detection platform through the same communication device. By adopting the specially-made static contact 3 of the communication device, unnecessary wiring is reduced, the wiring design among the devices is simplified, and the size of the detection platform is reduced.

Fig. 7 is a rear side view of a distribution transformer testing platform according to an embodiment of the present invention.

Optionally, as shown in fig. 2, 3 and 7, the distribution transformer detection platform further includes a high voltage testing device 60 and a movable sliding table 70; the high-voltage testing device 60 is fixed on a movable sliding table 70, the movable sliding table 70 is arranged in a carriage of the movable platform 10, and the movable sliding table 70 is electrically connected with the control device 30; the movable sliding table 70 is used for sliding the high-voltage testing device 60 out of the carriage of the movable platform 10 under the control of the control device 30; the high voltage testing apparatus 60 is used for performing a withstand voltage test on the transformer 50 to be tested.

Specifically, in order to reduce the volume and weight of the detection platform and fully utilize the internal space, the internal high-voltage test device 60 adopts the design of a movable sliding table, the high-voltage test device 60 slides out of the carriage of the movable platform 10 through the movable sliding table 70 when the high-voltage resistance test is carried out, and then the transformer 50 to be tested is connected with the high-voltage test device 60 for testing, so that the requirement of the safety distance during the high-voltage resistance test is ensured, and the requirement of the volume and weight of the equipment is also considered.

Optionally, as shown in fig. 2 and 7, the movable platform 10 includes a visible liquid crystal rearview mirror 11, at least two ultrasonic radars 12, a reverse image camera 13, and a warning light 14.

The visible liquid crystal rearview mirror 11, the reversing image camera 13, the ultrasonic radar 12 and the warning lamp 14 are all arranged on the outer side of the carriage of the movable platform 10; the image camera 13 and the ultrasonic radar 12 of backing a car all set up in the trailing flank of movable platform 10, and the image camera 13 of backing a car sets up in the upper portion intermediate position of trailing flank, and two at least ultrasonic radar 12 set up respectively in both sides about the trailing flank, and wherein, the trailing flank points to the leading flank and is the direction of advance of movable platform 10.

Specifically, the visible liquid crystal rearview mirror 11 can enable workers to observe surrounding obstacles when the distribution transformer detection platform moves directly and clearly, the ultrasonic radar 12 is used for detecting whether the distance between the distribution transformer detection platform and the obstacles is smaller than a safe distance or not in real time and sending out alarm prompt tones when the distance is smaller than the safe distance, the reversing image camera 13 is used for obtaining reversing images when the distribution transformer detection platform reverses, so that the workers can observe the reversing images through the visible liquid crystal rearview mirror 11, and the warning lamp 14 is used for carrying out self-checking on each device built in the distribution transformer detection platform and flickering to carry out fault prompt when faults are detected.

Optionally, as shown in fig. 2 and 3, the distribution transformer detection platform further includes a wiring prompt screen 80; the wiring prompt screen 80 is arranged outside the carriage of the movable platform 10, and the wiring prompt screen 80 is arranged on the outer surface of the carriage on the side of the movable platform 10 with the wiring port 101.

Specifically, the wiring prompt screen 80 may directly display a connection status between the distribution transformer detection platform and the to-be-detected money 50, and the staff may also directly send a wiring signal to the control device 30 through the wiring prompt screen 80, so as to realize automatic line switching between the distribution transformer detection platform and the to-be-detected transformer 50 through the control device 30.

Fig. 8 is a right side view of a distribution transformer testing platform according to an embodiment of the present invention.

Optionally, as shown in fig. 8, the distribution transformer testing platform further includes an electrical test operation panel 90; the electrical test operation panel 90 is disposed outside the cage of the movable platform 10.

Specifically, the railway carriage right side surface of movable platform 10 still is provided with electrical test operating panel 90, be provided with a plurality of control button on the electrical test operating panel 90, including power button, platform scram control button etc. can realize power control, removal scram control etc. to distribution transformer testing platform through electrical test operating panel 90 for the staff once only accomplishes distribution transformer testing platform and the transformer 50's that awaits measuring wiring back, and a key starts can accomplish automatically to the whole detection items of the transformer 50 that awaits measuring.

Optionally, as shown in fig. 8, the distribution transformer detection platform further includes a touch display screen 100; the touch display screen 100 is fixed to the outside of the vehicle compartment of the movable platform 10 through a foldable structure.

Specifically, the touch display screen 100 is a man-machine interaction unit of the distribution transformer detection platform, and is disposed on the outer surface of the carriage on the same side as the electrical test operation panel 90, so that the worker can issue various control instructions to the distribution transformer detection platform through the touch display screen 100, including sending a connection signal to the control device 30, so that the control device 30 controls the connection between the automatic switching line device 40 and the transformer 50 to be tested based on the connection signal, and the like.

The touch display screen 100 is fixed to the outer side of the carriage of the movable platform 10 by using a foldable structure, so that the touch display screen 100 can be folded upwards at a certain angle as required, and is convenient for a worker to operate and use.

Optionally, as shown in fig. 2 and 8, the distribution transformer testing platform further comprises a plurality of fans 110; the fan 110 is disposed on the roof of the movable platform 10.

Specifically, the top of the platform 10 is further provided with a plurality of fans 110 to dissipate heat of the distribution transformer detection platform and protect each device from faults due to overheating. For example, fig. 2 and fig. 8 show schematic diagrams of four fans 110, and the number of the fans 110 may be increased or decreased according to actual needs, which is not described herein again.

Optionally, the distribution transformer detection platform further comprises a power module for supplying power to the distribution transformer detection platform. This power module can charge the use repeatedly for distribution transformer testing platform also can detect the transformer 50 that awaits measuring under the operating mode that does not have external power supply.

Optionally, the distribution transformer detection platform further comprises a wireless communication module for realizing communication connection between the distribution transformer detection platform and the central control server, and through a wireless communication mode, wiring design is reduced, and a data interaction flow between the distribution transformer detection platform and the central control server is simplified.

Optionally, the control device 30 further has a self-checking function, and the control device 30 may perform self-checking on various functional modules such as the detection module 20 and the power module integrated inside the distribution transformer detection platform, control the warning light 14 to flash to prompt when a fault is detected, and display fault information on the touch display screen 100 to prompt a worker when a fault is detected.

Optionally, the control device 30 is further configured to, after receiving the detection data transmitted through the automatic switching line device 40, process and analyze the detection data to obtain a detection result, and generate a detection report according to the detection result. The detection report and the analysis process of each detection data can be called and checked by using the touch display screen 100, and can also be uploaded to a central control server through a wireless communication module for storage for subsequent use.

Use the embodiment of the utility model provides a distribution transformer testing platform has following advantage:

(1) flexible detection capability. Aiming at large-scale devices such as a box-type transformer which are inconvenient to hoist and transport, the distribution transformer detection platform can be flexibly moved to a side-open unfolding test of the box-type transformer.

(2) High integration and convenient replacement. By adopting an integrated structural design, all detection modules, power supply modules and the like are integrated in a box-type movable platform, and when any module fails, the module is quickly replaced in a pluggable mode, so that the normal operation of equipment is ensured; the crane lifting device has the advantages of small occupied area, no influence on crane lifting operation, good moving performance and capability of being pushed and pulled by a single person.

(3) The wire is connected once and the wire is switched automatically. The automatic wire switching device has the function of automatically switching wires, does not need manual wire switching in each test, and automatically switches wires by the intelligent automatic wire switching device according to test items, and comprises the functions of automatically switching wires on a high-voltage side, automatically switching wires on a low-voltage side and automatically shorting wires.

(4) One-key measurement. After the working personnel finish wiring, the system can automatically finish all transformer detection items of the station by starting one key.

(5) And (4) wireless communication. The distribution transformer detection platform and the central control server have a wireless communication function, and can perform wireless data interaction and upload data.

(6) And (4) self-checking function. The intelligent fault detection device has a self-checking function, performs self-checking on the built-in detection module, the power supply module and each action mechanism, and intelligently prompts faults.

(7) An alarm mechanism: and warning equipment such as an ultrasonic radar is arranged, so that the safety of workers is ensured.

In the description of the embodiments of the present invention, unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Finally, it should be noted that the above description is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (10)

1. A distribution transformer detection platform is characterized by comprising a movable platform, a detection device, a control device and an automatic switching line device;

the movable platform is a box-type vehicle body, and the detection device, the control device and the automatic switching line device are all arranged in a carriage of the movable platform; the detection device and the automatic switching line device are electrically connected with the control device;

the automatic switching line device comprises a plurality of wiring ends, wiring ports on the outer surface of a carriage of the movable platform correspond to the wiring ends one by one, the wiring ports are used for connecting transformers to be tested, and the automatic switching line device is used for connecting or disconnecting at least part of the wiring ends with the corresponding wiring ports under the control of the control device;

the detection device is used for detecting the delivery parameters of the transformer to be detected under the control of the control device;

the movable platform is used for driving the distribution transformer detection platform to move horizontally or lift.

2. The distribution transformer testing platform of claim 1, wherein the automatic switching line device comprises a high-side automatic switching line sub-device and a low-side automatic switching line sub-device;

the high-voltage side automatic switching wire sub-device comprises a plurality of high-voltage wiring terminals and a first driving module, wherein the first driving module is used for driving the high-voltage wiring terminals to be connected with or disconnected from the corresponding wiring ports;

the low-voltage side automatic switching wire sub-device comprises a plurality of low-voltage terminals and a second driving module, wherein the second driving module is used for driving the low-voltage terminals to be connected with or disconnected from the corresponding wiring ports.

3. The distribution transformer testing platform of claim 2, wherein the high-side auto-switching line subassembly further comprises a tulip contact mounting plate and a frame;

each high-voltage terminal comprises a static contact and a plum blossom contact which is arranged corresponding to the static contact; the first driving module comprises at least one electric push rod;

the static contact is electrically connected with the high-voltage side of the transformer to be tested through an outgoing line contact; the fixed contact is arranged on one side, close to the tulip contact, of the top plate of the rack, the outgoing line contact points are arranged on one side, far away from the fixed contact, of the top plate of the rack, and one outgoing line contact point is arranged corresponding to one fixed contact point;

the plum blossom contact is electrically connected with the control device through an incoming line contact; the tulip contacts are arranged on one side of the tulip contact mounting plate, the wire inlet contact points are arranged on one side, far away from the tulip contacts, of the tulip contact mounting plate, and one wire inlet contact point is arranged corresponding to one tulip contact;

the electric push rod is arranged on a side plate of the rack and used for pushing the tulip contact to be communicated with the static contact under the control of the control device.

4. The distribution transformer testing platform of claim 3, wherein the stationary contact comprises a first conductive structure and a second conductive structure, the first conductive structure is wrapped around the second conductive structure, and the first conductive structure and the second conductive structure are insulated from each other;

when the stationary contact is communicated with the plum blossom contact, the first conduction structure is used for transmitting a current signal, and the second conduction structure is used for transmitting a voltage signal.

5. The distribution transformer testing platform of claim 1, further comprising a high voltage testing device and a mobile slide;

the high-voltage test device is fixed on the movable sliding table, the movable sliding table is arranged in a carriage of the movable platform, and the movable sliding table is electrically connected with the control device;

the movable sliding table is used for sliding the high-voltage test device out of the carriage of the movable platform under the control of the control device;

the high-voltage test device is used for carrying out a voltage withstand test on the transformer to be tested.

6. The distribution transformer testing platform of claim 1, wherein the movable platform comprises a visible liquid crystal rearview mirror, at least two ultrasonic radars, a back-up image camera, and a warning light;

the visible liquid crystal rearview mirror, the reversing image camera, the ultrasonic radar and the warning lamp are all arranged on the outer side of the carriage of the movable platform; the image camera of backing a car with the ultrasonic radar all set up in the trailing flank of movable platform, just the image camera of backing a car set up in the upper portion intermediate position of trailing flank, at least two the ultrasonic radar set up respectively in both sides about the trailing flank, wherein, the trailing flank points to the direction of advance that the leading flank is movable platform.

7. The distribution transformer testing platform of claim 1, further comprising a wiring prompt screen; the wiring prompt screen set up in the railway carriage outside of movable platform, just the wiring prompt screen set up in movable platform has the railway carriage surface of wiring mouth one side.

8. The distribution transformer testing platform of claim 1, further comprising an electrical test operator panel;

the electrical test operation panel is arranged on the outer side of the carriage of the movable platform.

9. The distribution transformer testing platform of claim 1, further comprising a touch screen display; the touch display screen is fixed on the outer side of the carriage of the movable platform through a turnover structure.

10. The distribution transformer testing platform of claim 1, further comprising a plurality of fans; the fan is arranged on the top of the carriage of the movable platform.

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