Trina Solar Vertex S 420W vs Panasonic EverVolt 410

Our Verdict Winner: Panasonic EverVolt 410

The Panasonic EverVolt 410 wins this comparison by a decisive margin. It leads in efficiency (21.5% vs 21.3%) and matches or exceeds on warranty (25 vs 15 years). For most residential installations, the Panasonic EverVolt 410 is the stronger choice.

Power / Capacity

420W

410W

Efficiency

21.3%

21.5%

Warranty

15 yrs

25 yrs

Key Differences

• Trina Solar Vertex S 420W is rated at 420W while Panasonic EverVolt 410 is rated at 410W, a 10W difference.
• Panasonic EverVolt 410 achieves 21.5% efficiency vs 21.3% for the other, a 0.2 percentage point gap.
• Panasonic EverVolt 410 comes with a 25-year product warranty vs 15 years for the other.
• Panasonic EverVolt 410 has a superior temperature coefficient of -0.26%/°C vs -0.34%/°C, retaining more power in hot climates.
• Trina Solar Vertex S 420W uses PERC Mono cells while Panasonic EverVolt 410 uses HJT (Heterojunction) cells, representing different technology generations.

Specifications Breakdown

Module Efficiency

The Panasonic EverVolt 410 achieves 21.5% module efficiency compared to Trina Solar Vertex S 420W's 21.3%, meaning Panasonic EverVolt 410 converts 0.2 percentage points more sunlight into electricity per square meter. In practical terms, the Trina Solar Vertex S 420W produces 210.2 watts per square meter of panel area while the Panasonic EverVolt 410 produces 210.0 W/m². For rooftop installations where space is limited, this efficiency gap determines how many kilowatts you can fit on your available roof area. Over a 25-year system life, even a small efficiency advantage compounds into meaningful additional energy production.

Power Output

The Trina Solar Vertex S 420W delivers 420W per panel versus 410W for the Panasonic EverVolt 410, a 10W difference per module. To build an 8 kW residential system, you would need 20 Trina Solar Vertex S 420W panels or 20 Panasonic EverVolt 410 panels. Despite the per-panel wattage difference, both require the same number of panels for this system size due to rounding. Higher wattage per panel is particularly valuable for commercial-scale installations where panel count directly impacts balance-of-system costs.

Temperature Coefficient

The Panasonic EverVolt 410 has a temperature coefficient of -0.26%/°C versus -0.34%/°C for the Trina Solar Vertex S 420W. On a hot summer day when cell temperature reaches 65°C (40°C above the 25°C STC baseline), the Panasonic EverVolt 410 retains 94.8% of its rated power while the other retains 93.2%. This difference is particularly significant in hot climates such as the American Southwest, the Middle East, and Southeast Asia, where panels routinely operate 30-40°C above STC for several hours each day. Over the system lifetime, the cumulative energy advantage from a better temperature coefficient can amount to 2-4% of total production.

Warranty Coverage

The Trina Solar Vertex S 420W is backed by a 15-year product warranty and 25-year performance guarantee, while the Panasonic EverVolt 410 offers 25-year product and 25-year performance coverage. The Panasonic EverVolt 410 provides 10 additional years of defect protection, covering manufacturing issues, material failures, and premature performance loss. Based on their published degradation rates (1.5% first year then 0.5%/year for Trina Solar Vertex S 420W; 0.5% first year then 0.35%/year for Panasonic EverVolt 410), after 25 years the Trina Solar Vertex S 420W should retain approximately 86.5% of original output versus 91.1% for the Panasonic EverVolt 410. This 4.6 percentage point gap in end-of-life output meaningfully impacts lifetime energy economics.

Physical Dimensions & Weight

The Trina Solar Vertex S 420W measures 1762×1134×30mm and weighs 21.8 kg, while the Panasonic EverVolt 410 measures 1722×1134×30mm at 21.5 kg. 2.00 m² of panel area for the Trina Solar Vertex S 420W versus 1.95 m² for the Panasonic EverVolt 410. Their weights are closely matched, so neither panel imposes a significantly different structural load on the mounting system. Similar footprints mean both panels fit comparably on standard residential rooftop configurations.

Specification Comparison

Specification	Trina Solar Vertex S 420W	Panasonic EverVolt 410
Power	420W	410W
Efficiency	21.3%	21.5%
Power Density	19.5 W/sq ft	19.5 W/sq ft
Cell Type	PERC Mono	HJT (Heterojunction)
Bifacial	No	Yes
Weight	21.8 kg	21.5 kg
Temp Coefficient	-0.34%/°C	-0.26%/°C
Snow Load	5400 Pa	5400 Pa
Wind Load	2400 Pa	2400 Pa
Product Warranty	15 years	25 years
Performance Warranty	25 years	25 years
Degradation (Year 1)	1.5%	0.5%
Annual Degradation	0.5%	0.35%
Country	China	Japan

5-Dimension Head-to-Head Analysis

1. Efficiency & Power Density

Winner: Panasonic EverVolt 410

The Panasonic EverVolt 410 achieves 21.5% efficiency versus 21.3% — a 0.2 percentage point advantage. On a typical 30-panel residential roof, this translates to approximately 0.3 kW more total system capacity, or 2 kWh more annual production in an average US location.

2. Hot Climate Performance

Winner: Panasonic EverVolt 410

The Panasonic EverVolt 410 has a better temperature coefficient of -0.26%/°C versus -0.34%/°C. On a 45°C summer day (20°C above STC), the winner retains 94.8% of rated power versus 93.2%. This is a meaningful difference in hot states like Arizona, Texas, and Florida.

3. Durability & Warranty

Winner: Panasonic EverVolt 410

Panasonic EverVolt 410 leads with a 25-year product warranty versus 15 years. Panasonic EverVolt 410 degrades more slowly at 0.35% per year versus 0.5%. After 25 years, expect 86.5% vs 91.1% of original output for Trina Solar Vertex S 420W and Panasonic EverVolt 410 respectively.

4. Power Output

Winner: Trina Solar Vertex S 420W

The Trina Solar Vertex S 420W delivers 420W versus 410W per panel — 10W more. For an 8 kW system, you need 20 panels with the higher-wattage option versus 20 panels, saving 0 panels and the associated racking and labor costs.

5. Cell Technology

Winner: Panasonic EverVolt 410

The Trina Solar Vertex S 420W uses PERC Mono: PERC (Passivated Emitter Rear Cell) is the current mainstream technology, offering good efficiency at the lowest manufacturing cost. The Panasonic EverVolt 410 uses HJT (Heterojunction): HJT (Heterojunction) combines crystalline silicon with amorphous silicon layers, delivering the best temperature coefficient and bifacial gains, but at higher manufacturing cost. HJT (Heterojunction) represents a newer generation technology with a longer performance runway as manufacturing matures.

Trina Solar Vertex S 420W

The Vertex S (DE09R.08) is a proven PERC residential panel offering 420W with 144 half-cut cells in a compact form factor with reliable Trina Solar quality.

Pros

+ Proven PERC reliability
+ Competitive pricing
+ 144 half-cut cells for shade tolerance
+ Widely available

Cons

- Lower efficiency than N-type
- Higher degradation
- PERC technology limitations

View full Trina Solar Vertex S 420W specs →

Panasonic EverVolt 410

DISCONTINUED: Panasonic exited solar manufacturing in 2023. The EverVolt 410 offered Panasonic's HJT technology at a slightly more accessible price point while maintaining premium quality.

Pros

+ Panasonic brand quality
+ HJT cell technology
+ Good temperature performance
+ 25-year warranty

Cons

- DISCONTINUED - no longer manufactured
- No new units available
- No ongoing product support

View full Panasonic EverVolt 410 specs →

Choose Trina Solar Vertex S 420W If...

✓ You want fewer panels to reach your target system size, reducing racking and labor costs
✓ Cost-effective residential installations with proven technology.

Choose Panasonic EverVolt 410 If...

✓ Your roof space is limited and you need maximum power per panel
✓ Long-term warranty protection is a top priority and you plan to stay in your home for 25+ years
✓ You live in a hot climate (Arizona, Texas, Florida) where heat performance matters
✓ You want maximum output retention over the system's 25-30 year lifespan
✓ You prefer newer cell technology with a longer performance improvement runway

Our Recommendation

Recommended Panasonic EverVolt 410

The Panasonic EverVolt 410 is the decisive winner in this solar panel comparison, outperforming the Trina Solar Vertex S 420W in 4 of 5 dimensions. Unless you have a specific requirement that the Trina Solar Vertex S 420W uniquely addresses, the Panasonic EverVolt 410 is the stronger choice for virtually every installation scenario.

View Trina Solar Vertex S 420W specs → View Panasonic EverVolt 410 specs →

Frequently Asked Questions

Which is better, Trina Solar Vertex S 420W or Panasonic EverVolt 410?

Which panel is more efficient, Trina Solar Vertex S 420W or Panasonic EverVolt 410?

The Panasonic EverVolt 410 at 21.5% module efficiency. Higher efficiency means more watts per square foot of roof space, which is critical for space-constrained installations. The difference of 0.2 percentage points translates to approximately 10W per panel under standard test conditions.

Which has a better warranty, Trina Solar Vertex S 420W or Panasonic EverVolt 410?

The Trina Solar Vertex S 420W comes with a 15-year product warranty and 25-year performance guarantee. The Panasonic EverVolt 410 offers 25-year product and 25-year performance warranties. Panasonic EverVolt 410 provides 10 additional years of product coverage.

Which panel performs better in hot weather?

The Trina Solar Vertex S 420W has a temperature coefficient of -0.34%/°C and the Panasonic EverVolt 410 is -0.26%/°C. Panasonic EverVolt 410 retains more power in heat — important in states like Arizona, Texas, and Florida. A lower (less negative) temperature coefficient is better.

How many Trina Solar Vertex S 420W vs Panasonic EverVolt 410 panels do I need for an 8 kW system?

For an 8 kW system: you need 20 Trina Solar Vertex S 420W panels (420W each) or 20 Panasonic EverVolt 410 panels (410W each). The Trina Solar Vertex S 420W requires fewer panels, saving on racking hardware and installation labor.

Related Resources

View full Trina Solar Vertex S 420W specifications → View full Panasonic EverVolt 410 specifications → All Trina Solar products → All Panasonic products →

Last updated: February 2026