Pêşkêşkirina Lîganî ya Bherînê ji bo Tranformasyonên li Peldanka Metanî

Dişikên pad-ê yên transformatoran di seroperasyonda de derbarê çewtîna-xwe piştgiriya çend dengên herêmî yên li ser bingeha-herêm:

• Tripên pêşdeng/berzanebî: Di şertên berzanebî û pêşdeng derbasdar in û hewceyên trip kirin.

• Pêşandina fan û thermostat: Karûbardkirina dirêj fan vebirina malperdan rêvekirin, thermostatyan bigere, û disberkirina gawra çewt îlal bike, wekheviya operasyonê digere.

• Nivîsana fanê yeknîş: Fanên bi nivîsandin lêserê pelîkanê zor dike ku karwaz bikin ji bo xerîdar û wergirtina fan, ev nivîs da jî gawra çewt têne rakirin û derejeya çewta navenda sero bigere ve tevahî ya çewtê bibike.

Ji bo optimizasyona disberkirina çewtê, wanagirê ji analîza elementên endamî re modela 3D-a transformatorê dibexşînin. Bi nîşana qayeyên cihêreyê çewtê, ên dikarin navcheyên çewtên pêşdeng hilbijêrin û dizayna sistemê ya serfirazkirina çewtê pirsgirin bikin.

1. Pênawayên Bazuwa Cihêreyê

Bazuwa cihêreyê nîşan dide ku cihêreya dem û mekan biguhere, bi çewtgerdan, guher û dagilîya çewtê girîng hatine serbest. Ji bo transformatoran pad-ê, çewt di navên û windinkan de dest pê kê. Şert û dema karûbardkirinê dagilîya çewtê biguhere, û interakcyonên multi-medyaya (navên, windinkan, izolyasyon) dagilîya çewtê neyiş bike.

Çewt bi serguheriya conduction (dominant, çewt dike ji windinkan/navên bi resin izolasyonê werdigire, ewa çewt dike ji hêla havê rastik), û convection. Intensiviyêya serguheriya wekhev bi gardiantên cihêreyê re serbest—çewt dike ji komponentên pêşdeng bi resinên bi tenî û ewa çewt dike ji hêla havê rastik. Hesabkirina fluxa çewtê wekheviya diyar bikin:

Di formulê de: q nîşan dide densitiya fluxa çewtê;λ nîşan dide kondûtiviteya çewtê; ∂t/∂x gardianta cihêreyê, nîşan dide raşa guherniya cihêreyê bi derêjiya; n koefîsyenta vegerîna çewtê. Herdemê ku di navên din de cihêreyên ji bo derêjîn de heye, çewt dike bi xebitandina cihêreyê serbest, û ev statû ya xebitandina cihêreyê convection e. Di seroperasyonda pad-ê yên transformatoran de, çewt dike ji hêla navên û windinkan werdigire û bi havê serbest bike, u ewa guherîna cihêreyê di navendeyên navendî de serbest bike. Di vê procesan de, guherîna çewtê bi serguheriya convection re serbest bike, û ev bi formulê din nîşan dide:

Di formulê de, h nîşan dide koefîsyenta guherîna serguheriya convection, t_f nîşan dide cihêreya fluid, û t_w nîşan dide cihêreya navendî. Herdemê ku cihêreya navendî pêşdeng be, çewt radîasyonê were bike, kewasa çewt radîasyonê. Ewêda ku faktoran din ser ast, mîqdara radîasyonê di navendeyên din de guhernîna cihêreyê serbest bike (bi cihêreya navendî re). Di seroperasyonda pad-ê yên transformatoran de, pîlancê xwe ne bi çewt radîasyonê serest bike; otma cihêreya transformatorê stabîl bike, farsa çewt radîasyonê ya wê dike çewt serest bike, û ev proses bi formulê din nîşan dide:

Di formulê de, S nîşan dide raga radîasyonê, T nîşan dide cihêreya termodinamîk navendî, û σ nîşan dide sabîtkê radîasyonê. Ji bo dizayna sistemê ya serfirazkirina çewtê pad-ê yên transformatoran, metoda analîza elementên endamî (FEA) birkar e bi hesabkirina tevlên cihêreyê. Bi hesabkirin, cihêreya her nod navendî dikare biafet bike. Ev ji bo pîvan cihêreyên navendî ke di pratîka de zor dike afet bike, navcheyên pêşdeng dikarin afet bike, û ewa pêşandina analîza coupling. Pênawayên asayî ya barkeribîna bazuya cihêreyê bi FEA wekheviya dike:

• Discretize domaina fizîkîya sêdimîn;

• Bi fonksyonên nîşan bidin guhernîna cihêreyê ji hêla her nod navendî;

• Tevlên element dibexşînin;

• Elementan dibexşînin û excitasyonên derbarê navendîyan bikin;

• Tevlan bi herînî şertên cihêreyê serbest bikin;

• Hesabkirina çewtê ya her nod bikin;

• Derive the element temperature rise based on the temperature field equations.

2 Modeling and Temperature Field Simulation of Pad - Mounted Transformers
2.1 Finite Element Modeling

Table 1 lists the relevant parameters of the pad - mounted transformer selected in this paper. A finite element model is constructed based on these parameters. Subsequently, simplified models are established for the high - voltage winding, low - voltage winding, and iron core of the pad - mounted transformer.

During model construction, since the welded connections of the high - voltage winding outlet terminals are relatively firm, they are not taken into account in the initial design phase. For simplification, the iron core is modeled as a monolithic structure, with inter - laminar gaps ignored (these gaps are addressed by means of the properties of bulk silicon steel to account for the material conductivity). The 3D simulation model of the transformer is shown in Figure 1.

To analyze the effects of natural convection on heat dissipation, an external air domain (with dimensions of 5000mm×5000mm×3000mm) is added to the simulation environment, enabling realistic modeling of the airflow patterns around the transformer.

2.2 Enclosure Model of Pad-Mounted Transformer

The windings and iron core are modeled as heat sources, with their heat generation rates calculated based on transformer design parameters. The air domain is configured with pressure outlets at the top and inlets distributed along the bottom and sides, maintaining an ambient temperature set at 300K. During simulations, natural convection parameters are derived by selecting an appropriate turbulence model based on the Rayleigh number.

The enclosure geometry (Figure 2) is simplified due to its complex composite structure. The roof's perforated panels are neglected, treating the entire roof as a continuous air domain. Porous media are placed at the air outlets under the eaves to simulate flow resistance. The air domain around the enclosure's bottom support beams is considered interconnected. An additional 155mm - high air layer is added beneath the enclosure to account for the foundation's impact on heat dissipation.

In the established model, the pre - set bottom holes, top holes, and upper - lower holes all belong to porous media, with a thickness of 10 mm (such as the yellow - green block in Figure 3), thus simulating the mesh plate. The specification of the bottom hole is 1450 × 1200 mm², and the specification of the upper - lower holes is 550 × 500 mm². Three openings and an epoxy plate are also set in the model, and the openings are determined to be in an open or closed state according to the actual situation. Generally, if the floor - mounted type is adopted, the top hole, the epoxy plate, and Opening 1 are in an open state; if the bottom - holed type is adopted, the top hole, the bottom hole, and Openings 1/2/3 are all in an open state.

2.3 Temperature Field Distribution Analysis

Next, a finite element model is built by meshing the geometric model. Ensure unity of natural convection and internal mesh models, and refine meshing at enclosure holes and air interfaces to improve calculation accuracy. Based on the geometric model, the finite element model has 401,856 nodes and 518,647 meshes. Key settings for the pad - mounted transformer model:

• Fluid - structure interface: Air interface, no - slip state for heat conservation.

• Adiabatic surfaces: Top of the roof, sides of bottom support beams, and external air.

• Heat - conducting surfaces: Enclosure sides (1mm - thick steel plate), all enclosure walls (2mm - thick steel plate), with upper holes open and lower holes closed.

Using finite element software, the temperature field model shows: Windings have the highest temperature in the transformer, followed by the iron core; adjacent air temperature is also high, decreasing during air rise until matching ambient temperature at the pressure outlet. During operation, hot air expansion causes air accumulation and collisions between ambient and duct air (due to continuous heating and volume increase). Air viscosity affects duct flow and the flow field. Hot air accelerates near the ground and slows away; airflow - surface contact forms a thermal boundary layer, which, due to its thickness, reduces heat transfer coefficients, increasing temperature and air viscosity while decreasing flow velocity. Hot air alters the temperature above the transformer, with temperature proportional to thermal radiation.

3 Heat Dissipation Design of Pad - Mounted Transformers
3.1 Model Analysis

Pad - mounted transformers are arranged inside enclosures with a high safety level. To ensure smooth air circulation within the enclosure and give full play to the transformer's heat dissipation performance, axial flow fans need to be configured to discharge hot air from the equipment interior. Meanwhile, heat sinks are installed outside the enclosure to achieve heat exchange. Through heat exchange, the continuous circulation of air inside the transformer can be promoted.

During the operation of pad - mounted transformers, heat is mainly generated by windings and iron cores. Therefore, the design needs to focus on the air flow states of these two components and integrate the relevant elements for building the heat dissipation model.

3.2 Determination of Model Parameters

For pad - mounted transformers, the differences between indoor air parameters and temperature performance parameters are relatively small. When selecting silicon steel sheets, their heat resistance performance should be prioritized. Meanwhile, the numerical ratio of copper wires to insulating resin is analyzed to determine the thermal performance parameters.

3.3 Condition Setting

The average pressure at the air inlet and outlet of the pad - mounted transformer is one atmospheric pressure. Combined with the performance of the heat sink, the temperature of cold air is taken as the inlet condition to establish a finite element model, and the symmetry plane and air inlet - outlet direction are defined.

3.4 Result Analysis

After establishing the model and setting the boundary conditions, calculations are carried out. The analysis shows that the air outlet of the pad - mounted transformer is the hottest point, with a temperature reaching 394.5K (corresponding to a hot - spot temperature of 120.5℃). The hottest point of the iron core is far from the air outlet, and the calculated hot - spot temperature is 110℃. Moreover, the positions close to the air inlets and outlets have poor heat dissipation performance.

3.5 Inlet and Outlet Air Analysis

Simulate the change of air flow velocity: If the hot high - voltage winding is built - in close to the air outlet and the air outlet has a right - angle structure, it will affect the air pressure, making the air inside the encapsulation thin and unfavorable for heat dissipation.

Based on this, optimize the air outlet design: Move the air outlet upward by about 30cm, keep the height unchanged, and simultaneously reduce the width of the air inlet (mainly reduce by 10cm), so that the overall length of the enclosure increases by 20cm. After calculation, under this scheme, the hot - spot temperature and average temperature of the winding decrease significantly. Analyzing the air flow field velocity distribution, the winding air flow shows a 120° angle when transferred to the air outlet, indicating that the air flow is smooth.

3.6 Summary

Pad - mounted transformers play a crucial role in the power distribution system. If the large amount of heat generated during operation cannot be dissipated in a timely manner, it is likely to cause failures and threaten the stability of the system. Designers need to deeply analyze the heat dissipation problems of pad - mounted transformers, combine with the changes of the temperature field, use scientific methods such as the finite element method to build heat dissipation models, optimize the equipment's heat dissipation system, and improve the overall heat dissipation efficiency.