CN215119767U - Box-type substation based on IEC61850 communication protocol - Google Patents

Abstract

The utility model provides a box-type substation based on IEC61850 communication protocol, which comprises a temperature-sensing heat radiation component, a damp-proof heat radiation component and an irradiation and opening and closing component, the temperature-sensing radiating component comprises a first shell, a second shell, a supporting plate, a first exhaust fan, an air inlet pipe, an inclined plate, a condenser, a fan, a second exhaust fan, an air outlet pipe, a temperature sensor, a controller, a trapezoidal plate, a first groove, an L-shaped plate, a second groove, a third groove, a cylinder and a gasket, two second shells are symmetrically welded on the rear surface of the first shell, a supporting plate is welded on the inner side wall of each second shell, the upper surface of the supporting plate is provided with a first exhaust fan, the internal temperature is monitored in real time through a temperature sensor, and signals are transmitted to a controller, therefore, the controller controls the mechanism to cool and radiate, so that the manpower resource is saved, and the working efficiency of workers is improved.

Description

Box-type substation based on IEC61850 communication protocol

Technical Field

The utility model relates to a box-type substation technical field based on IEC61850 communication protocol, in particular to box-type substation based on IEC61850 communication protocol.

Background

The IEC61850 standard is the only global universal standard in the field of power system automation, and realizes the engineering operation standardization of the intelligent substation by realizing the standard, so that the engineering implementation of the intelligent substation becomes standard, uniform and transparent, the communication protocol refers to the rules and conventions that must be followed by both parties to complete communication or service, and the box-type substation is arranged for protecting the working operation of the two parties, but the existing box-type substation has certain defects;

when the internal device of the existing box-type substation runs, heat is generated, so that workers have to cool and radiate the internal device, and human resources are wasted;

the cooling equipment used at present comprises air cooling equipment and water cooling equipment, but the cooling cost of water cooling is high, the cooling effect of air cooling is slow, and along with the increase of the power of modules in the transformer substation, the cooling effect of the modules and the cooling effect of the modules are difficult to guarantee, so that the box-type transformer substation based on the IEC61850 communication protocol is provided.

SUMMERY OF THE UTILITY MODEL

In view of this, the embodiments of the present invention are intended to provide a box-type substation based on IEC61850 communication protocol, so as to solve or alleviate the technical problems existing in the prior art, and at least provide a useful choice.

The embodiment of the utility model provides a technical scheme is so realized: a box-type substation based on an IEC61850 communication protocol comprises a temperature-sensitive heat dissipation assembly, a moisture-proof heat dissipation assembly and an irradiation and opening and closing assembly, wherein the temperature-sensitive heat dissipation assembly comprises a first shell, a second shell, a supporting plate, a first exhaust fan, an air inlet pipe, an inclined plate, a condenser, a fan, a second exhaust fan, an air outlet pipe, a temperature sensor, a controller, a trapezoidal plate, a first groove, an L-shaped plate, a second groove, a third groove, an air cylinder and a gasket;

the welding of the back surface symmetry of first casing has two second casings, the inside wall welding of second casing has the backup pad, the last surface mounting of backup pad has first air exhauster, the second casing just is located with the adjacent one side of first casing the rear of first air exhauster air inlet is run through and is had the air-supply line, the inside wall welding of second casing has the swash plate, and the inclination of swash plate is the sixty-five degrees of horizontal direction, two condensers, two are installed to the inside wall symmetry of second casing adjacent one side of condenser just is located the inside of second casing has the fan through the round pin axle is articulated, the inside diapire welding of second casing has the second air exhauster, the second casing just is located with the adjacent one side of first casing the rear of second air exhauster gas outlet is run through and is had out the tuber pipe.

In some embodiments, the upper surface of the first shell is provided with a trapezoidal plate, two first grooves are symmetrically formed in two sides of the trapezoidal plate, two L-shaped plates are symmetrically welded to two sides of the trapezoidal plate, a second groove is formed in the inner side wall of each L-shaped plate, and rainwater can be drained conveniently by forming the first grooves and the second grooves.

In some embodiments, two third grooves are symmetrically formed in the lower surface of the trapezoidal plate, an air cylinder is welded to the top wall of the interior of each third groove, a gasket is bonded to the lower surface of each air cylinder, and the piston rod of each air cylinder reversely supports the trapezoidal plate to lift.

In some embodiments, the inner side wall of the first housing is respectively provided with a temperature sensor and a controller, so that the temperature sensor can detect the temperature inside the first housing.

In some embodiments, a moisture-proof heat dissipation component is arranged inside the temperature-sensitive heat dissipation component;

the damp-proof heat dissipation assembly comprises a U-shaped damp-proof plate, a fourth groove, a frame body, a first through hole, a connecting block, a sphere, a first fan blade, a second through hole and a second fan blade;

the lower surface welding of temperature sensing radiating component's first casing has dampproofing board of dampproofing radiating component's U type, the fourth recess has evenly been seted up to the lower surface of the dampproofing board of U type, prevents through the dampproofing board of U type that moisture from corroding first casing bottom.

In some embodiments, two frame bodies are symmetrically installed on two sides of the first casing, first through holes are uniformly formed in the inner side wall of the first casing and located inside the frame bodies, a connecting block is welded to the lower surface of the first through holes, first fan blades are hinged to the lower surface of the connecting block through spheres, and the first fan blades are arranged in the first through holes to rotate to achieve a heat dissipation effect.

In some embodiments, the upper surface of the first casing is uniformly provided with second through holes, the inner side walls of the second through holes are hinged with second fan blades through pin shafts, and the top of the first casing is cooled by arranging the second fan blades to rotate in the second through holes.

In some embodiments, the front surface of the temperature-sensing heat dissipation assembly is provided with an irradiation and opening and closing assembly;

shine and open and shut the subassembly and include lamp area, door body and handle:

the lamp area is installed to the inside roof of first casing, the front surface of first casing articulates through the hinge symmetry has two door bodies, the front surface mounting of the door body has the handle, and the staff of being convenient for opens the door body through the installation handle, and the lamp area of setting is convenient for the staff and is overhauld at any time quantum.

The embodiment of the utility model provides a owing to adopt above technical scheme, it has following advantage:

the utility model monitors the internal temperature in real time through the temperature sensor and transmits signals to the controller, so that the controller controls the mechanism to cool and radiate, thereby saving human resources and improving the working efficiency of workers;

two, the utility model discloses a first air exhauster absorbs steam, drives the fan during emission and rotates, gaseous flow with higher speed to when cooling down with the help of the condenser, increase cooling efficiency, and arrange air conditioning back inside the first casing through the second air exhauster, realize cold and hot circulation, utilize the cylinder jack-up trapezoidal plate to increase the heat dissipation at first casing top, thereby promote holistic cooling effect and radiating effect.

The foregoing summary is provided for the purpose of description only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present invention will be readily apparent by reference to the drawings and following detailed description.

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 embodiments or technical descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a side view of the structure of the present invention;

fig. 4 is a second housing structure of the present invention.

Reference numerals: 1. a temperature-sensitive heat dissipation assembly; 101. a first housing; 11. a second housing; 12. a support plate; 13. a first exhaust fan; 14. an air inlet pipe; 15. a sloping plate; 16. a condenser; 17. a fan; 18. a second exhaust fan; 19. an air outlet pipe; 20. a temperature sensor; 21. a controller; 22. a trapezoidal plate; 23. a first groove; 24. an L-shaped plate; 25. a second groove; 26. a third groove; 27. a cylinder; 28. a gasket; 3. a moisture-proof heat dissipation assembly; 301. a U-shaped moisture-proof plate; 31. a fourth groove; 32. a frame body; 33. a first through hole; 34. connecting blocks; 35. a sphere; 36. a first fan blade; 37. a second through hole; 38. a second fan blade; 4. an illumination and opening and closing assembly; 401. a light strip; 41. a door body; 42. a handle.

Detailed Description

In the following, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1-4, an embodiment of the present invention provides a box-type substation based on IEC61850 communication protocol, which includes a temperature-sensitive heat dissipation assembly 1, a moisture-proof heat dissipation assembly 3, and an irradiation and opening/closing assembly 4, where the temperature-sensitive heat dissipation assembly 1 includes a first housing 101, a second housing 11, a support plate 12, a first exhaust fan 13, an air inlet pipe 14, an inclined plate 15, a condenser 16, a fan 17, a second exhaust fan 18, an air outlet pipe 19, a temperature sensor 20, a controller 21, a trapezoidal plate 22, a first groove 23, an L-shaped plate 24, a second groove 25, a third groove 26, a cylinder 27, and a gasket 28;

two second casings 11 are symmetrically welded on the rear surface of the first casing 101, a supporting plate 12 is welded on the inner side wall of the second casing 11, a first exhaust fan 13 is installed on the upper surface of the supporting plate 12, an air inlet pipe 14 penetrates through the rear portion of an air inlet of the first exhaust fan 13 on one side, which is adjacent to the first casing 101, of the second casing 11, an inclined plate 15 is welded on the inner side wall of the second casing 11, the inclined plate 15 is inclined at sixty-five degrees in the horizontal direction, two condensers 16 are symmetrically installed on the inner side wall of the second casing 11, a fan 17 is hinged to the adjacent sides of the two condensers 16 and the inside of the second casing 11 through a pin shaft, a second exhaust fan 18 is welded on the inner bottom wall of the second casing 11, and an air outlet pipe 19 penetrates through the rear portion of the second exhaust fan 18 on one side, which the second casing 11 is adjacent to the first casing 101 and the rear portion of the air outlet of the second exhaust fan 18.

In one embodiment, the upper surface of the first casing 101 is provided with a trapezoidal plate 22, two first grooves 23 are symmetrically formed in two sides of the trapezoidal plate 22, two L-shaped plates 24 are symmetrically welded in two sides of the trapezoidal plate 22, a second groove 25 is formed in the inner side wall of each L-shaped plate 24, and the first groove 23 and the second groove 25 are formed to facilitate drainage in rainy weather.

In one embodiment, two third grooves 26 are symmetrically formed in the lower surface of the trapezoidal plate 22, the cylinder 27 is welded to the top wall of the interior of the third groove 26, the gasket 28 is bonded to the lower surface of the cylinder 27, the trapezoidal plate 22 is reversely jacked up by the piston rod of the arranged cylinder 27, heat dissipation is facilitated at the top of the first shell 101, and the installed gasket 28 prevents the piston rod from directly contacting the surface of the first shell 101.

In one embodiment, the temperature sensor 20 and the controller 21 are respectively installed on the inner side wall of the first casing 101, and the temperature inside the first casing 101 is monitored in real time through the temperature sensor 20.

In one embodiment, the temperature-sensing radiating component 1 is internally provided with a moisture-proof radiating component 3;

the damp-proof heat dissipation component 3 comprises a U-shaped damp-proof plate 301, a fourth groove 31, a frame body 32, a first through hole 33, a connecting block 34, a sphere 35, a first fan blade 36, a second through hole 37 and a second fan blade 38;

the lower surface welding of the first casing 101 of temperature sensing radiator unit 1 has dampproofing board 301 of the U type of dampproofing radiator unit 3, and fourth recess 31 has evenly been seted up to the lower surface of the dampproofing board 301 of U type, avoids the bottom of moisture erosion first casing 101 through the dampproofing board 301 of installation U type, and the even atress of fourth recess 31 of seting up to avoid dampproofing board 301 bottom of U type direct and ground contact.

In one embodiment, two frame bodies 32 are symmetrically installed on two sides of the first casing 101, a first through hole 33 is uniformly formed in the inner side wall of the first casing 101 and located inside the frame bodies 32, a connecting block 34 is welded on the lower surface of the first through hole 33, a first fan blade 36 is hinged to the lower surface of the connecting block 34 through a sphere 35, the connecting block 34 inside the first casing is connected with the first fan blade 36 through the first through hole 33, and the first fan blade 36 rotates inside the first through hole 33 by means of the connecting mode of the connecting block 34 and the first fan blade 36.

In one embodiment, the upper surface of the first casing 101 is uniformly provided with second through holes 37, the inner side walls of the second through holes 37 are hinged to the second fan blades 38 through pins, and the second through holes 37 are provided to facilitate connection of the second fan blades 38, so as to perform top heat dissipation.

In one embodiment, the front surface of the temperature-sensing heat dissipation assembly 1 is provided with an irradiation and opening and closing assembly 4;

the irradiation and opening and closing assembly 4 comprises a lamp strip 401, a door body 41 and a handle 42:

the lamp strip 401 is installed to the inside roof of first casing 101, and the front surface of first casing 101 articulates through the hinge symmetry has two door bodies 41, and the front surface mounting of door body 41 has handle 42, is convenient for the staff to open door body 41 with the help of handle 42, and the lamp strip 401 through the installation makes the staff can overhaul first casing 101 inside at any time quantum.

In one embodiment, the electrical output of the temperature sensor 20 is connected to the electrical input of the controller 21 through a wire.

In this embodiment: the model of the cylinder 27 is OSP-P40-00000-00900.

In this embodiment: the first suction fan 13 is of the type CX-125.

In this embodiment: the second suction fan 18 is of the type CX-150.

In this embodiment: the temperature sensor 20 is of the type LFH 101.

In this embodiment: the controller 21 is of the type DR 1-2000.

In this embodiment: the condenser 16 is model TLS.

The utility model discloses at the during operation, temperature sensor 20 monitors the temperature variation in the inside of first casing 101 in real time, when the temperature in the inside of first casing 101 reachs a definite value, temperature sensor 20 transmits the signal of receiving to controller 21, controller 21 controls first air exhauster 13, second air exhauster 18, condenser 16 and cylinder 27 and carries out work, the air intake of first air exhauster 13 absorbs the heat in the inside of first casing 101 through air-supply line 14 and discharges to the inside of second casing 11 through the air outlet of first air exhauster 13, with the help of swash plate 15, the air current drives fan 17 to rotate, the air current increases the velocity of flow through the rotation, cool the air current in the flow through condenser 16, the air current after the cooling utilizes the air intake of second air exhauster 18 to absorb, discharge back to the inside of first casing 101 through the air outlet pipe 19 through the air outlet of second air exhauster 18, the piston rod of cylinder 27 promotes first casing 101 and carries out reverse top and pushes trapezoidal plate 22, thereby carry out the separation of certain distance with trapezoidal plate 22 and first casing 101, thereby can utilize second through-hole 37 and second flabellum 38 to dispel the heat, and can avoid the rainwater to enter into first casing 101 inside rainfall weather, and can carry out effective drainage through first recess 23 and second recess 25 that trapezoidal plate 22 and L type plate 24 seted up, prevent that the rainwater from entering into first casing 101 inside, the dampproofing board 301 of U type of installation avoids first casing 101 bottom to receive the erosion of moisture, first flabellum 36 in the first through-hole 33 of first casing 101 both sides is used for the heat dissipation and the ventilation of temperature normal value.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of various changes or substitutions within the technical scope of the present invention, which should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. The utility model provides a box-type substation based on IEC61850 communication protocol, includes temperature sensing radiator unit (1), dampproofing radiator unit (3) and shines and open and shut subassembly (4), its characterized in that: the temperature-sensing heat dissipation assembly (1) comprises a first shell (101), a second shell (11), a supporting plate (12), a first exhaust fan (13), an air inlet pipe (14), an inclined plate (15), a condenser (16), a fan (17), a second exhaust fan (18), an air outlet pipe (19), a temperature sensor (20), a controller (21), a trapezoidal plate (22), a first groove (23), an L-shaped plate (24), a second groove (25), a third groove (26), an air cylinder (27) and a gasket (28);

the rear surface of the first shell (101) is symmetrically welded with two second shells (11), the inner side wall of the second shell (11) is welded with a support plate (12), the upper surface of the support plate (12) is provided with a first exhaust fan (13), the second shell (11) is adjacent to one side of the first shell (101) and is positioned at the rear part of an air inlet of the first exhaust fan (13) and penetrates through an air inlet pipe (14), the inner side wall of the second shell (11) is welded with an inclined plate (15), the inclined angle of the inclined plate (15) is sixty-five degrees in the horizontal direction, the inner side wall of the second shell (11) is symmetrically provided with two condensers (16), the adjacent sides of the two condensers (16) are positioned in the second shell (11) and are hinged with a fan (17) through a pin shaft, and the inner bottom wall of the second shell (11) is welded with a second exhaust fan (18), and an air outlet pipe (19) penetrates through the rear part of the air outlet of the second exhaust fan (18) at one side of the second shell (11) adjacent to the first shell (101).

2. The IEC61850 communication protocol-based box substation of claim 1, characterized in that: the upper surface of first casing (101) is equipped with trapezoidal plate (22), two first recesses (23) have been seted up to the bilateral symmetry of trapezoidal plate (22), the bilateral symmetry welding of trapezoidal plate (22) has two L template (24), second recess (25) have been seted up to the inside wall of L template (24).

3. The IEC61850 communication protocol based box substation of claim 2, characterized in that: two third grooves (26) are symmetrically formed in the lower surface of the trapezoidal plate (22), an air cylinder (27) is welded to the top wall of the inner portion of each third groove (26), and a gasket (28) is bonded to the lower surface of each air cylinder (27).

4. The IEC61850 communication protocol-based box substation of claim 1, characterized in that: and a temperature sensor (20) and a controller (21) are respectively arranged on the inner side wall of the first shell (101).

5. The IEC61850 communication protocol-based box substation of claim 1, characterized in that: a damp-proof heat dissipation component (3) is arranged in the temperature-sensing heat dissipation component (1);

the damp-proof heat dissipation assembly (3) comprises a U-shaped damp-proof plate (301), a fourth groove (31), a frame body (32), a first through hole (33), a connecting block (34), a ball body (35), a first fan blade (36), a second through hole (37) and a second fan blade (38);

the lower surface welding of first casing (101) of temperature sensing radiator unit (1) has dampproofing board (301) of U type of dampproofing radiator unit (3), fourth recess (31) have evenly been seted up to the lower surface of dampproofing board (301) of U type.

6. The IEC61850 communication protocol based box substation of claim 5, characterized in that: two frameworks (32) are installed to the bilateral symmetry of first casing (101), the inside wall of first casing (101) just is located first through-hole (33) have evenly been seted up to the inside of framework (32), the lower skin weld of first through-hole (33) has connecting block (34), the lower surface of connecting block (34) articulates through spheroid (35) has first flabellum (36).

7. The IEC61850 communication protocol based box substation of claim 5, characterized in that: second through-hole (37) have evenly been seted up to the upper surface of first casing (101), the inside wall of second through-hole (37) articulates through the round pin axle has second flabellum (38).

8. The IEC61850 communication protocol-based box substation of claim 1, characterized in that: the front surface of the temperature-sensing radiating assembly (1) is provided with an irradiation and opening-closing assembly (4);

the irradiation and opening and closing assembly (4) comprises a lamp strip (401), a door body (41) and a handle (42):

the lamp strip (401) is installed to the inside roof of first casing (101), the front surface of first casing (101) articulates through the hinge symmetry has two door bodies (41), the front surface mounting of door body (41) has handle (42).

Images