The first challenge when entering the renewable energy industry is understanding how to design and install projects. These articles are dedicated to teaching you the basics of how to design and install solar PV, solar thermal, and geothermal projects.

If you’re brand new

Click here to learn what is NABCEP and wether or not you should need to get the certification. If you’re serious about the solar industry and you want to get the NABCEP Certification, but you need to understand how exactly to apply, you can read more about getting the NABCEP Certification here.

Articles That Will Help You
A Review of Solar and Geothermal Certifications, Licenses and Permitting
Solar Thermal Design and Installation Guide

Solar PV Design and Installation Guide
How to Design a Solar PV Array and Estimate Power Production
Geothermal Design and Installation Bundle

SolarPro, HeatSpring, Ryan Mayfield Launch Megawatt Solar Design Class

 The online technical training experts at HeatSpring have teamed up with photovoltaic design and instruction professional Ryan Mayfield and technical media specialists SolarPro to launch a 10-week online course in megawatt-scale solar PV system design. To learn more about the course, register for one of two premium webinars being offered:

Cost Effective Megawatt Design with Ryan Mayfield on Tuesday May 20th at 1pm EST.

The Megawatt Design class is a technically rigorous and challenging 10-week course. Click this link for a complete commercial solar design training description and to claim one of thirty $500 bird discounts that are available.
The course has been developed for professionals who are responsible for designing, specifying, permitting, and managing the construction of megawatt-scale large-commercial solar projects and who need to stay current on equipment selection, design, budgeting, and code compliance. It is tailored to professionals with previous experience in large-commercial PV system design as well as those seeking to expand into the commercial market from a base of experience in residential PV system design. Students will use computer aided drafting, industry specific design tools and spreadsheet tools to complete the course.
Graduates of the Megawatt Design class will:

Submit a complete set of drawings, equipment, budget, code references, and calculations for an actual megawatt PV system design project.
Understand how to design projects that are cost effective, structurally sound, high performance and code compliant.
Understand the current best practices for line side connections, grounding, rapid shutdown, fire regulations, and other complex and common design challenges for large projects.
Be confident that their permitting package will be Code compliant the first time.

Course Outline

Project Qualification: In this opening week, we will review best practices for technical sales on large-scale commercial projects. Topics include: Establish major project goals, array location possibilities, rooftop/carport/ground mount, roof loading considerations, electrical infrastructure.
Equipment Selection: In this module we dive deeply into equipment selection. Pricing and equipment change rapidly in our industry. We’ll make sure you’re up to speed on the latest thinking. Topics include: Product selection thresholds, first cost, warranty, manufacturer service, module considerations including warranties and PID, inverter considerations, dc-to-ac ratio, micro/string/central inverter options, tracked and fixed racking, and system BOS.
Site Selection: This week we’ll cover requirements and best practices for siting your projects, covering both ground mount and rooftop systems. Topics include: Permissible shading allowances and  grading requirements for ground mounted arrays.
Software Tools: What software should you use to design large commercial solar projects? We’ll review the available options and help you to get the most out of your current or future program of choice, enabling fast, efficient design.
Designing Systems for Different Criteria: Every system design requires trade-offs. This week will cover how to optimize your designs for different criteria and how to minimize the downside of the trade-offs you make. Topics include: Lowest first cost, maximized energy production and targeted energy production.
NEC Considerations: Code, Code, Code. We could spend the entire course covering code, but we’re going to assume everyone in this course has a firm grasp of the NEC. This week we’ll discuss some of the 2014 updates and nuanced details to help you make fewer mistakes and get your jobs permitted faster.
Fire Code Considerations: Large-commercial rooftop systems require an in-depth understanding of fire codes and techniques for coordinating with fire departments, inspectors and owners.2012  International Fire Code (IFC) requirements will be covered.
Operations & Maintenance: Develop a detailed O&M plan that can be refined and re-used on your next large-commercial PV project.
Permitting: How do you get your permitting done faster and cheaper? That’s the multi-million dollar question. In this module we’ll provide tips and tools for getting your projects permitted more easily than your competitors.
Capstone Project: Students will receive all the inputs for a large-commercial rooftop installation, and develop and submit drawings, equipment and budgets to get the project installed as quickly and inexpensively as possible without compromising performance. Data for the capstone project comes from a real job. We’ve masked the identity of the project, but you’ll get to see all of the choices that were made and discuss the pros and cons of each as you do the work of designing your own system.

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April 7th, 2014|Categories: Geothermal and Solar Design and Installation Tips, Solar, Solar Design & Installation, Utility-Scale Solar|Tags: , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , |
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5 Perspectives for Using Solar Subcontractors for Residential PV Installation

This is a guest post by Fred Paris. Fred teaches our 6 week Solar Startup Accelerator where students get the tools (budgeting, planning, pricing, project management) and business plan they need to start new solar business or solar division within an existing company, in 6 weeks. You can read more about the Solar startup class […]

March 26th, 2014|Categories: Geothermal and Solar Design and Installation Tips, Solar, Solar Design & Installation|Tags: |
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How to Design Homes to be Solar PV Ready

Many homeowners  might be building a new home or doing renovations and they want solar, but not right now. The following is a guest post from Jamie Leef, an expert builder and solar installer at S+H Construction that will be helpful to general contractors and architects that are advising their clients. Jamie is also teaching a course for architects and engineers on design considerations for integrating solar in urban areas.

If you’re an architect or engineer advising clients about solar PV in urban areas, click here to sign up for Jamie’s course “Solar PV Design Considerations in Urban Areas”

By making a few changes to the building while construction is under way, you can make installing solar MUCH cheaper when they finally decide to invest in solar.

[gravityform id=”53″ name=”Solar PV Ready For General Contractors, Engineers, and Architects”]

Enter Jamie Leef

This is standard document we provide to firms we work with to advise their clients. In any place where I say “we” you can substitute with “solar contractor”

If you’d like me to BID on a solar project. Here is my contact information

Jamie Leef

Division Manager

Renewable Energy and Green Building

Office: 617-876-8286

Cell: 617-901-5522

Jamie@sandhsolar.com

Design Homes to be Solar PV Ready Summary.

PV systems have three key components:  Roof- or ground-mounted panels, DC-AC power conversion equipment mounted either at the panels or in a mechanical space, and balance-of-system gear that measures, controls, and connects the parts to each other and to the electrical grid.

Keep these things in mind when designing or analyzing a residence for a solar PV project:

The roof needs solar access!  This generally means an area of flat roof, or pitched south-facing roof, that is unshaded and large enough for the panels.  A typical 4 kW array is about 270 SF.  Modules are in units of approximately 40” x 66”, though other sizes can be found.
The roof structure needs to be able to handle an additional load of 3 to 4 pounds per square foot.
Your client should like the way the panels and proposed layout look.
The roof cladding should have a standard manufacture’s detail for attaching something to it.  All typical materials do – fiberglass/asphalt, EPDM, TPO, slate, etc.
The building should have an electric meter owned by a customer who uses a good amount of electricity.  Condos, for instance, can get complicated.
The building should have electric service from a utility that offers net metering and PV interconnection.  Some space should be set aside near the main electric panel for solar power equipment.  The amount of space varies by system type, but is usually about 4’ x 4’
A conduit will be run from the PV equipment location to the PV panel mounting install area.  This can be inside the building, on on the outside.

Other Kinds of Installs

Okay, so your project does not look like the other cookies that the cookie cutter created.  Here are some other scenarios to consider.

Consider a ground-mounted system if your roof can not take panels
Within some utilities and areas you can share net metering credits with other meters, which can allow for installs in condos, for instance, to pay back to several residents.
If you can not get an interconnection agreement, consider going off grid!  We have even done this in downtown Boston.  Ask us how.
Remember that solar hot water takes less space on the roof.  It also works very well in multifamily buildings where there is a shared water meter and hot water distribution system.

Solar Ready Details.

The following are things that should be done to design or prepare a residence for a solar PV project.

Ensure the roof has the structural capacity to accommodate the panels
Rough-in an unbroken metal conduit from the PV equipment location to the PV panel mounting install area.  There are to be no accessible pull-boxes or ways to access the DC conductors.  Please refer to section 690 of the NEC, and to the local AHJ for the conduit material options.  Large systems with a central inverter might have several DC conductors in this conduit.  Micro-inverters will have conductors designed for AC.  Size the conduit accordingly. If you have questions about sizing conduit call S+H Solar HERE
Label the conduit with “Solar PV Circuit” labels as per 690 NEC
Please discuss the specific site requirements for future access to cathedral ceilings, attic spaces, and the possible exterior conduit paths.
For exterior conduits we strongly recommend metal pipe or flex rather than plastic pipe for durability and temperature correction reasons, even if code does not require it.
Provide a 4’ wide ¾” plywood mounting panel adjacent to the main electric panel that is at least 4’tall and centered at 4’ AFF, but can be taller if possible.  Ensure there are similar electric code restrictions to this space, such as no water above, 3’ clearance in front, and free air above and below, etc.  Micro-inverter systems do not require this much space, but it will never go to waste.
Ensure that the proposed PV system back fed breaker rating is no more than 20% of the bus-bar rating of the main electric panel. For example, for a 200 AMP main breaker, the maximum overfeed is 40 AMP.  There are other optional interconnection points, depending on the utility and the service details.   If you there are multiple breakers, if this is multi-family home, or a small service and you have questions, please contact S+H Solar:
Leave a two-pole breaker blank space at the bottom of the bus-bar reserved and labeled for use as the PV back-feed breaker (or the section of bus that is opposite the service cable feed lugs or breaker).
Endure space for a small AC side-arm disconnect next to the exterior service entrance (assumed to be an electric meter cabinet).  Install a capped, waterproof conduit to that location for future AC wiring from the PV equipment panel if that location will be otherwise hard to wire to in the future (for instance, complicated foundation finishes insulation, or finished basement).
Provide a terminated CAT5-E or better, data cable to the main house router for monitoring at the PV equipment mounting location.

[…]

June 24th, 2013|Categories: Geothermal and Solar Design and Installation Tips, Solar, Solar Design & Installation|Tags: , , , |
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Real Time Data on Actual Geothermal COPs – Part 2 of Lessons Learned from 100,000 Hours+ of Real Time Geothermal Monitoring Data

This is a very nervous time for the geothermal industry and I can feel it when I’m on the phone with installers. There’s a lot of geothermal companies that have been around for 20+ years and now there’s a lot of innovation happening around policy, real time monitoring, and playing around with different ground loop heat exchangers, that industry veterans haven’t had to deal with before and it’s uncomfortable for them.

Here’s my main message to the geothermal industry: if you’re asking everyone to look at new ways to heat and cool buildings, you also need to be looking at new technologies, policies, and ways of doing things yourselves. Some of you are, but on average I notice more hesitancy within the industry than excitement about embracing (inevitable) change. I could be wrong on this, just my perception.

Monitoring projects means that we’re going to find great, good, and bad systems. In fact that’s the goal. Matt is a little more soft spoken so he wouldn’t say this, but yes, we will find bad systems.

With that being said, I’m super excited to be working with Matt and publishing this data. There’s only a small group of things the geothermal industry can do to proactively (unlike waiting around for fuel prices to increase by 300%) increase the adoption of the technology; including working for better policy, better ground loop innovations, decreasing customer acquisition costs, and verification of system performance.

Geothermal technology has a low margin of error, if anything is messed up during the design, installation and (most overlooked) operation of the system, the efficiencies will be shot. Here’s some of the interesting bits of information that can easily be found monitoring more than just kWh of the system:

How much does the COP drop due to pumping losses
Equipment failures; low refrigerate, valves, and pumps.

If you want more on monitoring check out these previous resource:

Performance Based Contracts Are the Future of Geothermal
Lessons Learned about Ground Loop Sizing from 100,000+ Hours of Real Time Geothermal Monitoring 
Free Course: How to Install, Commission and Use Real Time Geothermal Monitoring

Matt and Ground Energy Support’s data is a robust but small sample size, compared to the whole industry. But it shows the possibilities of what we can figure out with a larger sample size and more data. If you’re a manufacture, distributor, installer or driller, utility, or state energy official and would like to go a monitoring and verification study. Feel free to call me, Chris Williams at 800 393 2044 ex. 33, or Matt Davis at (603) 867-9762

Future posts will include

Geo Monitoring Quality over Quantity: Why All Data is Not the Same
Characteristics of the Best Monitoring and Verification Study
How Monitoring can Eliminate, or Prevent, Angry Customers Once and For All
Expected Versus Actual Performance: Comparing LoopLink Predictions to GES Data

Enter Matt Davis from Ground Energy Support

Introduction

This article is the second in a three-part series prepared by Ground Energy Support LLC (GES) that will highlight some of the lessons learned from over 100,000 hours of real-time ground source heat pump (GSHP) monitoring data. This is written for GSHP installers of residential and light commercial systems who want to learn how to leverage real-time Performance Monitoring to build better GSHP systems, reduce their risk and callbacks, and ensure customer satisfaction.

The previous article focused on showing how data from real-time monitoring can be used to assess how the ground loop is performing relative to both the installed capacity and the measured heating load. The daily load profiles presented in that article are now available to GxTracker™ users as part of their Performance screens (login required to view Load Profile graph).

This article focuses on the overall system performance, factors that affect performance, how real-time monitoring can be used to evaluate performance of installed equipment, and identify and address issues before they become problems.

The number of sites represents a relatively small sample size and the different measurement techniques used at the sites result in different levels of accuracy.  In spite of these limitations, we are able to identify and illustrate several factors that affect system performance.   As more sites are instrumented with web-based monitoring systems that have the capability of quantifying ground loop performance, geoexchange, and electrical consumption, there will be an unprecedented ability to assess a wide range of GSHP designs over a wide range of geologic and climatic conditions.
Measuring GSHP System Performance
GSHP systems have the potential to significantly reduce the energy needs for space heating and cooling (an estimated 4 Quadrillion BTUS in the US) and reduce greenhouse gas emissions. However, these benefits will only be realized if the systems operate efficiently. Efficient operation requires proper design, installation, and maintenance.

One common method for assessing system performance of residential systems is to review the customer’s electric bills on a regular basis. While lower electric bills are a clear indication that the systems are operating efficiently, it is often difficult to parse out other factors that contribute to the overall electrical consumption. Additional challenges to using a customer’s electric bill to assess system performance include: new construction has no baseline for comparison; retrofits will often combine the addition of a heat pump with other efficiency measures, making it difficult to attribute the savings to the GSHP; and finally, when an electric bill is higher than expected, the cause may be unrelated to the GSHP system. One of the biggest disadvantages of relying on electric bills as a measure of system performance is that the homeowner is left to identify and report GSHP performance problems. In short, the most effective way to demonstrate that a GSHP system is performing efficiently, and thus ensure customer satisfaction, is to monitor the system in real-time so as to assess key performance metrics.

Many factors contribute to the overall performance of a GSHP system. Through our monitoring activities to date, we have found the main factors to be:

Heat pump performance and ground loop temperature
Pumping energy necessary to circulate loop fluid
Heat pump cycling patterns
Auxiliary electric heat

One of the key metrics of assessing how a GSHP system is performing in heating mode is the Coefficient of Performance (COP). The COP is the ratio of useable thermal energy to the thermal equivalent of the electricity used to operate the system.

While measuring the COP is not always the primary objective, all of our real-time monitoring systems include, at a minimum, measurements of entering and leaving water temperature (EWT and LWT), heat pump status, and an estimate of fluid flow. When power measurements are not available, power consumption is modeled using the heat pump specifications, a pump penalty based on type of system and flowrate, and measured runtimes. These methods provide representative values of COP with an error of +/- 20% and are intended to show overall trends in system behavior.

In some installations, a higher level of accuracy is desired and additional measures of power consumption and, if necessary, flowrate can be included. When accurate measures of both flow and power consumption are available, the accuracy of the COP improves to approximately +/-5%.

Because the accuracy of the computed COP varies from site to site and quality assurance measures are necessary to insure the values are representative, COPs are not computed automatically as part of our performance metrics. Rather, the necessary components are available by downloading either the minute-resolution observations or integrated daily values.
Daily Average System COPs

The Daily COP values presented in Figure 1 and summarized in Table 1 illustrate some of the main factors that affect performance. Overall, there is an upward trend in performance as heat pump technology has gone from single stage to multi-stage compressors.

The system with the lowest performance (Site A) has single stage heat pumps using a standing column well. The two-stage heat pump on a standing column well (Site B) has a higher COP, but is adversely affected by the power required for fluid pumping. The COP of the two-stage system on the closed vertical loop (Site C) varies more through the year due to both the change in EWT and the use of the auxiliary electrical heat in late February. The performance of the two-stage system using two well groundwater loop (Site D) is comparable to, and slightly higher than, the other two-stage heat pump systems. The system with a variable stage heat pump (Site E) has the highest average COP. This is likely due to a combination of the variable-stage technology and its geographic location which enabled it to maintain higher EWTs throughout the winter.

These COP values are consistent with those reported by Puttagunta and others in their 2010 study of residential GSHPs. We have also found that, while the in-field performance is typically less than the AHRI rating, the systems are seen to provide a reliable technology for heating and cooling at consistently lower cost than conventional systems.
Table 1: Seasonal Average System COPs, Winter 2012-2013

Site
System Description
Average COP

A
Standing Column Well, 2 Heat Pumps, Single Stage
2.74

B
Standing Column Well, 1 Heat Pump, Two Stage
3.15

C
Closed Vertical Loop, 1 Heat Pump, Two Stage
3.27

D
Open Two Well System, 1 Heat Pump, Two Stage
3.33

E
Closed Horizontal Loop, 2 Heat Pumps, Variable Stage
4.18

Factors that affect System COP
There are several factors that affect the overall GSHP system performance. Because of the wide range in GSHP system designs and equipment available, there is not a single best approach to optimizing performance. Rather, we show how monitoring can help characterize the elements that affect specific installations. Again, the lessons learned and examples presented in this initial series of articles focuses on heating mode and uses examples from installations ranging from US Climate Zones 4 to 1.
Heat Pump Cycling
It has long been recognized that rapid cycling of heat pumps diminishes performance and increases mechanical wear on the equipment. In recent years, more efficient dual stage heat pumps have become common that enable heat pumps to operate for longer cycles, produce lower heat output, and use less electricity.

Figure 2 shows the heat pump cycle patterns for three different systems: one with two single-stage heat pumps, a two-stage heat pump, and one with a variable-stage heat pump. While the single-stage heat pumps reach their expected heat of extraction (~22MBtuH for the 3 ton and ~40MBtuH for the 5 ton), the average production of the heat pumps (while running) over this same period was 17 MBtuH and 32 MBtuH, about 20% below their steady state production. In contrast, the two-stage heat pump is able to maintain its steady state heat production in part load for cycles of approximately 30 minutes and then, when additional heat is necessary, switch into full load. With two-stage heat pumps there is much less efficiency lost from cycling on and off. The final example is a new variable stage heat pump that operates over extended periods of time, adjusting the heat output to meet demand. In general, the lower stages provide greater performance by varying heat output over multiple stages thereby increasing overall performance.
Loop Temperature
Entering water temperature is well-recognized as one of the leading factors affecting system performance and heat pump manufacturers provide performance specifications for temperature ranging from 25 to 100 ° F.

In the example shown below (Case A from last week’s article on Loop Performance), the power consumption of the heat pump circuit (which includes the flow center), and the Auxiliary electric heat are being monitored separately with a WattNode power meter. The COP is calculated for 15-minute intervals through the 2012-2013 winter. To remove the variability of performance associated with the heat pump cycling on and off, we only include 15-minute intervals for which the heat pump was running continuously. The EWT ranges from 33 to 51 °F. While there is an overall correlation between COP and EWT, there is also considerable variability at a given temperature.

[…]

June 16th, 2013|Categories: Geothermal and Solar Design and Installation Tips, Geothermal Heat Pumps|Tags: , , |
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Lessons Learned from 100,000 Hours+ of Real Time Geothermal Monitoring Data – Part 1

This is a guest article by Matt Davis, co-founder of Ground Energy Support (GES). GES provides a top quality real time monitoring package for monitoring geothermal heat pumps. Matt is an expert in geothermal monitoring. Matt has over 25 years of experience in data collection, analysis, geology and modeling of groundwater systems. He is now bringing that expertise and passion to help address the number one research priority in DOE’s recently updated GSHP Roadmap, see below “Collect/Analyze Data from GHP Systems”

Matt is an extremely active member of the ASTM committee that is working to develop heat metering standards in the United States. This committee is extremely important for implementing production based incentives for renewable thermal technologies and the lack of such a standard has been holding up the implementation of New Hampshire SB 218, the first production based renewable thermal incentive in US. This standard will also have implications for Massachusetts Bill SD 1593, which will create a production based incentive for renewable thermal technologies in Massachusetts, if it passes.

Matt is without question a top US expert on monitoring ground source heat pumps and he has the data to prove it 😉
A Few Odds and Ends Really Quick

If you’d like a larger copy of the data and graphs in this article, you can download it here. 

If you want to learn more about monitoring, all of it’s applications, how to install and commission it, and MUCH more, click here to sign up for the free product training on real time geothermal heat pump monitoring.
Curious about using real time monitoring to guarantee performance? Click here to read and download Matt’s white-paper on using real time monitoring to guarantee performance. 

This Series of Articles on Geothermal Monitoring Lessons Learned is for 2 Audiences 
1. Geothermal professionals that want to remove risk and improve their designs.

Never have angry customers again, because you can set up alerts.  Remove your risk, especially drillers, by being able to objectively calculate how much energy was extracted from the ground.

In the geothermal industry, I see three main groups. We can call them, the bottom 50%, the middle 45%, and the top 5%. The bottom 50% of the industry are the notorious, yet elusive “hacks” that everyone in the geothermal industry complains about. This technology is not for them, because it would show them how bad their work is. The top 5% is what I’ll call the geothermal old guard. These are companies that have been doing geothermal for 30 years+ and have a set standard of their ways, and don’t feel that they need to verify anything. They “know” it works. The middle 45% is really the group of contractors that is new to the geothermal industry, are extremely business savy and very confident in the quality of their designs and installations. You want monitoring to verify your designs, removes risk from your businesses and sell more jobs.

2. Policy Makers in New England

The second major group is policy makers in New England (particularly Massachusetts, hey guys!) that are now looking more and more into renewable thermal technologies and want real data on how the systems are performing. On the policy front, I’ll be doing following up posts on solar thermal and hopefully advanced biomass as well.
3 Geothermal Trends We Can be Proactive About
There are only four that I’ve been watching (click here to read 4 Trends Driving the Geothermal Industry) and working on lately that are exciting me about the geothermal industry. There’s only three that was can actually do anything about. First, policy. Second, how can we shove plastic in the ground in different configurations to decrease ground loop costs. Third, real time monitoring. Fourth is rising fuel costs, which we don’t have control over.

The geothermal industry is filled with people that think everyone outside of the industry are trying to stop the adoption of ground source heat pump. So, instead of thinking about what we PROACTIVELY do to further our industry, too much time is spent talking about what other people need to do.

Monitoring is critical because it is something we can proactively do that we solve a lot of problems.

1. “Geothermal is too expensive” –> Wrong, it’s not expensive. We don’t have the right policy in policy to support adoption. We need verified data to implement policy. Mark Faulkenberry from Western Farmers Electric Co-ops data is a good start on the utility side, we need more.

2. “The public needs to be better educated” –> Wrong. We, as in industry, need to be better marketers, salespeople, and communicators and prove the value to them. This starts with verifying performance claims.

What all of this means is that adoption of real time monitoring of geothermal systems is one of the most important things we need to start doing as an industry
Enter Matt Davis from Ground Energy Support
This article is the first in a 3-part series that will highlight some of the lessons learned from over 100,000 hours of GSHP real-time monitoring data. This is written for GSHP installers of residential and light commercial systems who want to learn how to leverage real-time Performance Monitoring to build better GSHP systems, reduce their risk and callbacks, and ensure customer satisfaction.

The overall goal of this Performance Monitoring series is to engage the GSHP community in a discussion of both 1) what is possible and 2) what is useful. This first article focuses on how web-based performance monitoring data can be used to assess the performance of the ground loop relative to installed capacity. The second article will focus on using performance monitoring data to assess the overall performance (COP) of the system and how the ground loop, heat pump, and loop pump all contribute (or limit) system performance. The third and final article will discuss how performance monitoring can be used to develop and implement performance guarantee contracts. This initial series of artilcles will focus on heating applications in residential and light-commercial installations. Cooling applications that will be addressed in future articles this Fall.
Loop Temperature
There is a growing consensus (e.g. “Ground Loop Performance”) that monitoring Entering Water Temperature (EWT) is important, relatively easy, and helps to identify problems in system performance. There is less agreement as to what the minimum entering water temperature should be for a specific application or whether adhering to a uniform standard (e.g. ISO 13256) is best for all clients under all conditions. Regardless of your design preference and practice, EWT should be monitored to ensure that your systems are operating within the design limits.

As shown in Figure 1, there is a wide range of behavior in the EWT of GSHP systems in the Northeast. The variation is due primarily to differences in design and use. All loops shown in the graph below are vertical boreholes, but they range in design from open diffusion (one well for groundwater extraction and another for groundwater return), standing column wells with various levels of bleed, to closed loop systems. Geographically, they range from Connecticut to southern New Hampshire. The residential systems are dominantly used for heating and the commercial installation has a significant cooling load for most of the year.

While the minimum EWT is a good indicator of ground loop conditions, the average of the entering and leaving water temperatures [½(EWT+LWT)] is a more meaningful metric for evaluating how the ground loop is performing relative to heating and cooling load.
Building Load
Real-time monitoring data can be used to track building load under a wide range of conditions and assess system performance. Building load provides a critically important context for interpreting loop temperature data, as it enables the installer to demonstrate that their system is operating as designed and isolate factors that are outside of their control. For example, construction practices (insulation of windows and door jams, proper ductwork installation) can have a significant impact on an GSHP system. The installer is often provided the building specifications and leaves it to the building contractors to meet those specification and can’t be on site to inspect all phase of construction or renovation. If the building envelope is not on spec, problems that arise in the heating/cooling system will like fall in the lap of the installer — why isn’t the system working? Also, installers can’t control homeowner’s thermostat settings, some of which may affect the efficiency of the system. However, by monitoring the system load, installers can identify discrepancies between operating and design conditions — discrepancies that may impact system performance and customer satisfaction.

 

The total building heat load is the sum of the GeoExchange and the heat produced by the compressor. In this discussion of Performance Monitoring, we focus on the GeoExchange portion of the building load as it is readily measured and is most closely tied to Ground Loop Performance. GeoExchange [MBtu/hr] is measured by multiplying the temperature difference (EWT – LWT) by the mass flow rate and the specific heat capacity of the circulating fluid.

[…]

June 2nd, 2013|Categories: Geothermal and Solar Design and Installation Tips, Geothermal Heat Pumps|Tags: |
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