Connecting Solar to the Grid is Harder Than You Think
Summary
TLDRThe video script discusses the challenges and opportunities associated with inverter-based resources like solar panels and wind turbines on the electrical grid. It highlights the Odessa power plant incident in 2022, where a small fault led to a significant loss of generation capacity, exposing the vulnerabilities of the grid to unexpected disturbances. The script explains the role of inverters in converting DC power from renewable sources to AC for the grid and the need for grid-following inverters to synchronize with the grid's phase and frequency. It also touches on the importance of managing grid frequency for stability and the potential of inverters to provide a sustained response to grid disturbances. The video emphasizes the ongoing efforts to improve the reliability and resilience of the grid as renewable energy sources become more prevalent.
Takeaways
- đĄ A lightning arrestor failure at a power plant in Odessa, Texas, caused a significant drop in electricity generation, highlighting the vulnerability of the grid.
- đ The unexpected loss of 2,500 megawatts, mainly from solar plants, showed that renewable energy sources can have unforeseen reactions to grid disturbances.
- đ The Texas grid's loss of frequency stability nearly led to an emergency situation, demonstrating the importance of maintaining grid balance between generation and demand.
- đ Inverter-based resources like solar panels and batteries output direct current (DC), which must be converted to alternating current (AC) to integrate with the grid.
- đ Advancements in inverter technology are crucial for managing the increasing integration of renewable energy sources into the power grid.
- đ The variability of renewable energy sources, such as solar and wind, presents challenges in maintaining a stable grid frequency, which is critical for the proper functioning of electrical devices.
- đ Grid-following inverters synchronize with the grid's phase and frequency but require additional mechanisms to manage frequency deviations and maintain stability.
- đ The growth of inverter-based resources worldwide is driving the need for engineering solutions to ensure grid reliability and resilience.
- đ ïž Maximum Power Point Trackers (MPPTs) optimize the power output from solar panels by adjusting resistance based on changing conditions like sunlight and temperature.
- đš Protective systems for grid-connected renewable energy sources must balance between preventing damage and maintaining grid stability during faults.
- đ Inverter technology offers opportunities for more flexible and responsive power management, including the development of grid-forming inverters for independent power supply.
Q & A
What event triggered the power grid disturbance in Odessa, Texas on June 4, 2022?
-The power grid disturbance was triggered by the failure of a lightning arrestor at a power plant in Odessa, Texas.
How much generation capacity was lost when the Texas grid lost power during the 2022 event?
-The Texas grid lost 2,500 megawatts of generation capacity, which is roughly 5% of the total demand.
What type of power plants were mainly affected by the fault in the 2022 Odessa event?
-The main power plants affected were solar plants spread throughout the state.
What is the role of 'Resource Loss Protection Criteria' in the power grid?
-The 'Resource Loss Protection Criteria' defines the minimum loss of power that requires having redundancy measures in place to prevent emergencies.
What is the significance of the system frequency dropping to 59.7 hertz during the event?
-A system frequency drop to 59.7 hertz indicates a significant imbalance between power generation and demand, which could lead to disconnecting customers to reduce demand and prevent aæŽäž„éç emergency.
How do solar panels and batteries typically output power?
-Solar panels and batteries typically output power in the form of direct current (DC).
Why is it necessary to convert DC power from renewable sources to AC for the grid?
-The grid predominantly uses alternating current (AC) because it allows for the use of simple and inexpensive transformers to change voltage along the transmission path, providing flexibility and efficiency in long-distance power transmission.
What is the primary function of a Maximum Power Point Tracker (MPPT)?
-The primary function of an MPPT is to adjust the resistance in a solar panel system to optimize power output by constantly following the maximum power point, which changes with varying sunlight and temperature conditions.
How do grid-following inverters synchronize with the grid?
-Grid-following inverters synchronize with the grid using a phase-locked loop circuit that senses the grid's voltage and sets the timing of internal switches to match the grid's phase and frequency.
What is the challenge associated with inverter-based resources during under-frequency events?
-During under-frequency events, inverter-based resources need to inject more energy into the grid to prevent frequency from dropping too low. However, this requires running the plant below its maximum capacity, which can be costly and less efficient.
What is the concept of 'ride-through' in the context of grid faults?
-'Ride-through' refers to the ability of inverters to continue supplying power to the grid and provide support during faults, instead of tripping offline or reducing power, thus preventing cascading outages.
What is the potential of inverters in addressing the engineering challenges of the modern power grid?
-Inverters have the potential to address engineering challenges by providing more responsive and flexible control over power flow, improving the integration of renewable energy sources, and contributing to a more reliable, sustainable, and resilient grid.
Outlines
đ Power Grid Disturbance in Odessa, Texas
The video script begins with an account of an incident on June 4, 2022, where a lightning arrestor at a power plant in Odessa, Texas, failed, causing a part of the plant to go offline. This was a typical fault that occurs occasionally in the power grid. However, this event was unique as it led to a massive loss of 2,500 megawatts of generation capacity, primarily from solar plants, causing a significant drop in system frequency. The incident nearly led to an emergency situation where customers might have been disconnected to reduce demand. The video's host, Grady, introduces himself and sets the stage for a discussion on inverter-based resources on the grid, highlighting the challenges of integrating renewable energy sources like solar and wind with the existing power infrastructure.
đ The Role of Inverters in Renewable Energy
Grady delves into the role of inverters in renewable energy systems, explaining that solar panels and batteries produce direct current (DC), which is not compatible with the alternating current (AC) used by the power grid. He discusses the evolution of inverters from mechanical devices to modern solid-state electronic circuits, which use pulse width modulation to create a sine wave output. The video also touches on the importance of Maximum Power Point Trackers (MPPTs) in optimizing the power output of solar panels by adjusting to changing conditions like sunlight and temperature. Grady emphasizes the need for inverters to synchronize with the grid's phase and frequency and the challenges they face in maintaining grid stability, particularly during disturbances.
đ« Challenges of Inverter-Based Resources
This section of the script addresses the engineering challenges associated with inverter-based resources like solar panels and wind turbines as they become a larger part of the power generation mix. Grady explains the critical role of grid frequency in maintaining balance between generation and demand and the potential consequences when this balance is disrupted. He discusses the need for primary frequency response and the limitations of grid-following inverters, which lack the physical inertia of traditional power plants. The script also covers the complexities of managing under-frequency events, the economic trade-offs of maintaining reserve capacity, and the protective systems required to prevent damage to renewable resources during grid faults.
đ The Future of Inverter Technology and the Grid
In the final paragraph, Grady expresses optimism about the future of inverter technology and the power grid. Despite the current challenges, he highlights the rapid advancements in inverter technology and its potential to create a more reliable, sustainable, and resilient grid. He mentions grid-forming inverters that can operate independently of the main grid, which could be a significant step forward. Grady also shares his enthusiasm for independent creators and their authentic, original content, segueing into a discussion about Nebula, a streaming service for independent creators. He encourages viewers to subscribe to Nebula for early access to his content and to support independent creators who represent the future of great video.
Mindmap
Keywords
đĄlightning arrestor
đĄgrid frequency
đĄinverter-based resources
đĄmaximum power point tracker (MPPT)
đĄfrequency response
đĄsolar plants
đĄwind turbines
đĄpower conversion equipment
đĄgrid-tied inverter
đĄfault ride-through
đĄrenewable energy
Highlights
On June 4, 2022, a lightning arrestor at a power plant in Odessa, Texas, failed, causing a significant drop in the Texas grid's generation capacity.
The fault at the Odessa power plant resulted in a loss of 2,500 megawatts, highlighting the vulnerability of the grid to such events.
Solar plants, which were at peak output during the incident, were disproportionately affected by the fault, dropping system frequency to 59.7 hertz.
The event nearly triggered Texasâs 'Resource Loss Protection Criteria,' which would have required disconnecting customers to reduce demand.
The power industry was alarmed by the unexpected reaction of solar plants to the initial disturbance.
Investigations revealed that it was not equipment failure but rather the reaction of power conversion equipment to the disturbance that caused the drop in solar plant production.
Solar power's share of the grid is rapidly increasing, posing new engineering challenges for integrating these sources with the existing grid infrastructure.
Inverter-based resources, such as solar panels and batteries, work on direct current (DC) but must be converted to alternating current (AC) to integrate with the grid.
Mechanical inverters have been largely replaced by solid-state electronic circuits, which are more efficient and offer better control over the conversion process.
Cheap inverters produce a rough approximation of a sine wave, while more sophisticated ones use pulse width modulation to create a smoother output.
Grid-tie inverters must synchronize with the grid's phase and frequency and control voltage to manage power flow.
Inverter-based resources can only function when the grid is operational, unlike traditional power plants that can provide backup during outages.
Solar panels have an optimal power point that changes with temperature and sunlight intensity, requiring Maximum Power Point Trackers (MPPT) for efficiency.
Frequency stability on the grid is critical for maintaining balance between generation and demand, with deviations leading to potential equipment malfunctions.
Primary Frequency Response is a mechanism to quickly inject power into the grid during unexpected generation losses to stabilize frequency.
Inverter-based resources, such as solar and wind farms, are increasingly required to participate in primary frequency response to support grid stability.
Energy markets incentivize power plants to maintain reserve capacity to respond to under-frequency events, which can affect profitability.
Inverter-based resources must manage grid faults without overly sensitive protective systems to prevent cascading outages.
Grid-forming inverters represent an advancement, capable of black starting or supporting an isolated grid without reliance on a larger operational grid.
The growth of inverter-based resources presents both challenges and opportunities, with the technology improving rapidly to support a more reliable and sustainable grid.
Transcripts
On June 4, 2022, a small piece of equipment (called a lightning arrestor) at a power Â
plant in Odessa, Texas failed, causing part of the plant to trip offline. It Â
was a fairly typical fault that happens from time to time on the grid. Thereâs a Â
lot of equipment involved in producing and delivering electricity over vast distances, Â
and every once in a while, things break. Breakers isolate the problem, Â
and we have reserves that can pick up the slack. But this fault was a little bit different.
Within seconds of that one little short circuit at a power plant in Odessa, Â
the entire Texas grid unexpectedly lost 2,500Â megawatts of generation capacity (roughly 5%Â Â
of the total demand), mainly from solar plants spread throughout the state. For some reason, Â
a single 300-megawatt fault at a single power plant magnified into a loss of two-and-a-half Â
gigawatts, dropping the system frequency to 59.7 hertz. The event nearly exceeded Texasâs Â
âResource Loss Protection Criteria,â which is minimum loss of power that requires having Â
redundancy measures in place. Another fault in the system could have required Â
disconnecting customers to reduce demand. In other words, it was almost an emergency.
If you lived in Texas at the time, you probably didnât notice anything unusual, Â
but this relatively innocuous event sent alarm bells ringing through the power industry. Â
Solar plants, large-scale batteries, and wind turbines donât produce power like conventional Â
thermal power plants that make up such a big part of the grid. The investigation into the Â
2022 Odessa disturbance found that it wasnât equipment failures that caused all the solar Â
plants to drop so much production all at once, at least not in the traditional sense. Instead, Â
a wide variety of algorithms and configuration settings in the power conversion equipment Â
reacted in unexpected ways when they sensed that initial disturbance.
The failure happened just before noon on a sunny summer day, so solar plants around Â
the state were at peak output, representing about 16% of the total power generation on the Â
grid. That might seem high, but there have already been times when solar was powering Â
more than a third of Texasâs grid, and that number is only going up. The portion of the Â
grid comprised of solar power is climbing rapidly every year, and not just in Texas, Â
but worldwide. So the engineering challenges in getting these new sources of power to play nicely Â
with the grid that wasnât really built for them are only going to become more important. And, Â
of course, I have some demos set up in the garage to help explain. Iâm Grady and this is Practical Â
Engineering. In todayâs episode, weâre talking about inverter-based resources on the grid.
Solar panels and batteries work on direct current, DC. If you measure the voltage coming out, Â
itâs a relatively constant number. This is actually kind of true for wind turbines Â
as well. Of course, they are large spinning machines, similar to the generators in coal Â
or natural gas plants. But unlike in thermal power plants that can provide a smooth and Â
consistent source of power through a steam boiler, winds vary a lot. So, Â
itâs usually more efficient to let the turbine speed vary to optimize the transfer of energy from Â
the wind into the blades. There are quite a few ways to do this, but in most cases, Â
you get a variable-speed alternating current from the turbine. Since this AC doesnât match the grid, Â
itâs easier to first convert it to DC. So you have this class of energy sources, Â
mostly renewables, that output DC, but the grid doesnât work on DC (at least not most of it).
Nearly all bulk power infrastructure, including the power that makes it into your house, Â
uses an alternating current. I wonât go into the Tesla versus Edison debate here, Â
but the biggest benefit of an AC grid is that we can use relatively simple and inexpensive Â
equipment (transformers) to change the voltage along the way. That provides flexibility between Â
insulation requirements and the efficiency of long-distance transmission. So we have to convert, Â
or more specifically invert, the DC power from renewable sources onto the AC grid. In fact, Â
batteries, solar panels, and most wind turbines are collectively known to power professionals as Â
âinverter-based resourcesâ because they are so different from their counterparts. Hereâs why.
The oldest inverters were mechanical devices: a motor connected to a generator. This is pretty Â
simple to show. I have a battery-powered drill coupled to a synchronous motor. When Â
I pull the trigger, the drill motor spins the synchronous motor, generating a nice sine wave Â
we can see on the oscilloscope. Maybe you can see the disadvantages here. For one, Â
this is not very efficient. There are losses in each step of converting electricity to mechanical Â
energy and then back into electrical energy on the other side. Also, the frequency depends on Â
the speed of the motor, which is not always a simple matter to control. So these days, Â
most inverters use solid-state electronic circuits, and look what I found in my garage.
These are practically ubiquitous these days, partly because cars use a DC system, Â
and itâs convenient to power AC devices from them. I just hook it up to the battery, and Â
get nice clean power from the other endâŠ
haha just kidding. These cheap inverters definitely output Â
alternating current, but often in a way that barely resembles a sine wave. Connecting a load Â
to the device smooths it out a bit, but not much. Thatâs because of whatâs happening under the hood. Â
In essence, switches in the inverter turn on and off, creating pulses of power. By controlling the Â
timing of the pulses, you can adjust the average current flowing out of the inverter to swing up Â
and down into an approximate sine wave. Cheaper inverters just use a few switches to create a Â
roughly wave-like signal. More sophisticated inverters can flip the switches much more quickly, Â
smoothing the curve into something closer to a sine wave. This is called pulse width modulation. Â
Boost the voltage on the way in or the way out, add some filters to smooth out the choppiness of Â
the pulses, and thatâs how you get a battery to run an AC device⊠but itâs not quite how Â
you get a solar panel to send power into the grid. There is a lot more to this equipment.
For one, look at the waveform of my inverter and the one from the grid. Theyâre similar enough, Â
but theyâre definitely not a match. Even the frequency is a little bit off. I will not be Â
making an interconnection here, since I donât have a permit from the utility, but even if I did, this Â
inverter would let out the magic smoke. A grid-tie inverter has to be able to both synchronize with Â
the phase and frequency of the grid and be able to vary the voltage of the waveform to control how Â
much current is flowing into or out of the device. The synchronization part often involves a circuit Â
called a phase-locked loop. The inverter senses the voltage of the grid and sets the timing of all Â
those little switches accordingly to match what it sees. So, these are often called grid-following Â
inverters. They synchronize to the grid frequency and phase and only vary the voltage to control the Â
flow of power. And that hints at one of their challenges: they only work when the grid is up.
Iâve done a video all about black starts, so check that out after this if you want Â
to learn more, but (in general), inverter-based resources like solar, Â
wind, and batteries can only follow whatâs already on the grid. When the systemâs down, Â
they are too, regardless of whether the sunâs shining or the windâs blowing. Thatâs why Â
most grid-tied solar systems on houses canât give you power during an outage.
Thereâs another interesting thing that inverters do for solar panels, and I can show you how it Â
works in my driveway. Â
I have a solar panel hooked up to a variable resistor, and IâmÂ
measuring the voltage and current produced by the panel. You can see as I lower the resistance, Â
the output voltage of the panel goes down and the current it supplies goes up. But this isnât a Â
linear effect. I recorded the voltage and current over the full range, and multiplied them together Â
to get the power output. If you graph the power as a function of voltage, you get this shape. And you Â
can see thereâs an optimum resistance that gets you the most power out of the panel. Itâs called Â
the maximum power point. If you deviate on either side of it, you get less power out. In other Â
words, youâre leaving power on the table. Youâre not taking full advantage of the panelâs capacity.
Whatâs even more challenging is that point changes depending on the temperature of the Â
panel and the amount of sun hitting it. I ran this test again with a few more clouds, Â
and you can see how the graph changes. So nearly all large solar photovoltaic installations use Â
whatâs called a Maximum Power Point Tracker (or MPPT) that essentially adjusts the resistance to Â
follow that point as it changes with sunniness and temperature. Itâs really a separate device Â
from the inverter, but often theyâre located right next to each other or inside the same Â
housing. Even this panel came with a charge controller that has this MPPT function, Â
and you can see it adjusting the flow of current to constantly try and stay at the Â
peak of the curve while it charges this battery. These can be used for an entire installation, Â
but in many cases, each panel or group of panels gets its own MPPT because that Â
curve is just a little bit different for each one. Tracking the peak power Â
output individually can often squeeze a little more capacity out of the system.
Squeezing out capacity is essential to address another challenge associated with inverter-based Â
resources on the grid: frequency. Â Â
The rate at which the voltage and current on the grid swing
back and forth is an important measure of how well generation and demand are balanced. If demand Â
outstrips the generation capacity, the frequency of the grid slows down. Lots of equipment, both on Â
the generation side and the stuff we plug in, is designed to rely on a stable grid frequency, so if Â
it deviates too far, stuff goes wrong: Devices malfunction, motors can overheat, generators Â
get out of sync, and more. Itâs so important that rather than let the frequency get too far Â
out of whack, grid operators will disconnect customers to get electrical demands back in Â
balance with the available supply of power, called an under-frequency load shed. Things go wrong on Â
the grid all the time, so generators have to be able to make up for contingencies to keep the Â
frequency stable. Hereâs the quintessential example: an unexpected loss of generation.
Say a generator trips offline, maybe because of a failed lighting arrestor like the Odessa example. Â
The system frequency immediately starts dropping, since power demand now exceeds the generation. And Â
the frequency will keep dropping unless we inject more power into the system. The first part of Â
that, called Primary Frequency Response, usually comes from automatic governors in power plants. Â
If we do it fast enough, the frequency will reach a low point, called the nadir (NAY-dur), and then Â
recover to the nominal value. The nadir is a critical point, because if it gets too low, Â
the grid will have to shed load in order to recover. The other important value is called Â
the rate-of-change-of-frequency, basically the slope of this line. It determines how much Â
time is available to get more power into the system before the frequency gets too low, Â
and there are several factors that play into it: How much generation was lost in the first place, Â
how quickly we can respond, and how much inertia there is on the grid. Thermal power plants that Â
traditionally make up the bulk of generating capacity are gigantic spinning machines. Theyâre Â
basically a bunch of synchronized flywheels. That kinetic energy helps keep them spinning Â
during a disturbance, reducing the slope of the frequency during an unexpected loss.
Maybe you can see the problem with a simple grid-following inverter. Itâs locked in phase Â
with the frequency, even if that frequency is wrong. And it has no physical inertia to Â
help arrest a deviation in frequency. If we keep everything the same and just increase Â
the share of inverter-based resources, any loss of generation will mean a steeper slope, Â
reducing the time available to get backup supplies onto the grid before itâs forced Â
to shed load. Larger renewable plants, like solar and wind farms, are increasingly required Â
to participate in primary frequency response, injecting power into the grid immediately when Â
the frequency drops. And some inverters can even create synthetic inertia that mimics a turbineâs Â
physical response to changes in frequency. But thereâs another challenge to this.
Dealing with an over-frequency event is relatively straightforward: just reduce the amount of energy Â
youâre sending into the grid. But, response to an under-frequency event requires you to Â
have more energy to inject. In other words, you have to run the plant below its maximum capacity, Â
just in case it gets called on during an unexpected loss somewhere else in Â
the system. For a power company, that means leaving money on the table, so in most places, Â
the energy markets are set up to pay power plants to maintain a certain level of reserve capacity, Â
either through operating below maximum output or including battery storage in the plant.
The last big thing that inverter-based resources have to manage is faults. Of course, you need Â
protective systems that can de-energize solar or wind resources when conditions on the grid could Â
lead to damage. These are expensive projects, and thereâs almost no limit to the things that can go Â
wrong, requiring costly repairs or replacement. But, for the stability of the grid, you canât Â
have those protective systems being so sensitive that they trip at the hint of something unusual, Â
like what happened in Odessa. This concept is usually referred to as âride-through.â Â
Especially for under-frequency events, you need inverters to continue supplying Â
power to the grid to provide support. If they trip offline, or even reduce power, Â
in response to a disturbance, it can lead to a cascading outage. This is kind of a tug of Â
war between owners trying to protect their equipment and grid operators saying, âHey, Â
faults happen, and we need you not to shut the whole system down when they do.â And Â
reliability requirements are getting more specific as the equipment evolves, Â
because every manufacturer has their own flavor of protective settings and algorithms.
As inverter-based resources continue to grow rapidly in proportion to the overall generation Â
portfolio, their engineering challenges are only becoming more important. We talked about a few Â
of the big ones: lack of black start ability, low inertia, and performance during disturbances. And Â
there are a lot more. But inverters also provide a lot of opportunities. Theyâre really powerful Â
devices, and the technology is improving quickly. They can chop up power basically however you want, Â
and they arenât constrained by the physical limitations of large generating plants. So Â
they can respond more quickly, and, unlike physical inertia that will eventually peter out, Â
inverters can provide a sustained response. There are even grid-forming inverters that, Â
unlike their grid-following brethren, can black start or support an isolated island Â
without the need for a functioning grid to rely on. Weâre in the growing pains stage right now, Â
working out the bugs that these new types of energy generation create, Â
but if you pay attention to whatâs happening in the industry, itâs mostly good news. A lot of Â
people from all sides of the industry are working really hard on these engineering challenges so Â
that weâll soon come out with a more reliable, sustainable, and resilient grid on the other end.
I build a lot of homemade demonstrations for videos like this one, and I hope it Â
comes across how much joy it gives me. I love the challenge of making something useful with Â
constraints on budget and tools. But Iâve never built a hot air balloon! One of my Â
fellow creators who runs the Neo channel just released a video on this incredible Â
story of two families escaping East Germany in maybe the most creative way possible.
I donât know about you, but I have to say that almost everything I watch these days is produced Â
by independent creators. Thereâs just something really authentic and original about content that Â
hasnât had to go through 5 levels of studio executives before it gets made. Neoâs episode Â
on The Balloon Escape is a perfect example. Just a fascinating story about homemade engineering, Â
including an interview with one of the men who made the attempt, all set to the Â
beautiful animations theyâre known for. And, if you want to see it, itâs only available on Nebula.
You probably know about Nebula now, even if youâre not subscribed. Itâs a streaming service Â
built by and for independent creators. No studio executives deciding what gets the green light, Â
no algorithm driving the content into a single style, and no ads getting in Â
the way. We just released a huge update that completely redesigned the home page, Â
making it easier to find new stuff in addition to your favorites. There's tons of originals, and weâre always adding creators, Â
so the new categories can help you discover content related to your interests.
My videos go live on Nebula before they come out here, and my Practical Construction Â
series, where I embedded on a construction site for a year, was specifically produced Â
for Nebula viewers who want to see deeper dives into specific topics. I know there are a lot of Â
streaming platforms out there right now, and no one wants another monthly cost to keep track of, Â
but I also know that if youâre watching a show like this to end, there is a ton of Â
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