The baseline needs to follow the Appendix G rules. So it is a system 1 or 2 and it needs to be auto-sized by the software according to G3.1.2.8.

1) Schedule the lighting based on the expected occupancy pattern. If the lights in a certain area would normally be off then schedule it that way.
2) I assume you are talking about a control that responds to daylight. If so this is a viable control strategy and you can claim savings. So the "schedule" does not have to be identical if that is the only way you can model the savings (do an exceptional calculation). In many energy modeling software you can model such a control directly (keeping the schedules the same and avoiding the exceptional calculation).

I am purposefully trying NOT to take "credit" for switching the lighting off, because I have no "automated" control. I would make use of the lighting level control functionality of energyplus to model user behaviour to switch the lights off when my near passive house zone is receiving many thousands of watts of direct solar radiation to avoid the useless extra light from the electric light and save some energy and avoid overheating this solar sensitive space.

Theoretically schedules are free to define as long as they are the same for the baseline, right? But is automated control used to model user behaviour (the same control in both baseline and design) allowed?

Take it a step further and apply the same logic to blinds that are user operated, or windows that are opened for natural ventilation.

I think you are getting my question...

Always helpful to understand the motivation behind the questions!

Technically you are correct about the schedules and manual controls. Table G3.1 does indicate that the schedules must be typical and are subject to approval by the rating authority (GBCI). The reality is that schedules are typically not submitted or reviewed for LEED so no one would likely question it. Using automated control (a schedule) to simulate user behavior is technically not allowed but since you are keeping the schedules the same it would likely be acceptable.

One could certainly argue that you are modeling the building as accurately as you can. So if there is a conflict with the "rules" I tend to vote for the accuracy.

Thanks Marcus. I hate being an experimental rat, but in this particular case, I may need to.

A related question...if it turns out that my naturally ventilated building with radiant floor heating manages to get under 300 hours for the heating loads not met hours (assuming the cooling setpoint is set to some high setpoint so as to not turn on and I'm just concerned with heating load not met hours), it is more than likely that the unmet load hours from the baseline case is much less than that of my designcase model, simply because heating with air is much faster response time wise than radiant surface heating, i.e. the differential is very likely to exceed the required 50 hours.

May it be valid to decrease the heating sizing parameter of the baseline case to something less than 1.25, to increase the unmet load hours until they are within 50 of the designcase model?

I know this stuff is not exactly in the standard. Just like to hear your opinion.

You are allowed to do so based on G3.1.2.2. Make sure you have tried everything else first before reducing baseline capacities as this should be your last resort to get the unmet load hours in alignment. I reviewed a project recently where the capacities were reduced well under 100% and it calls into question the accuracy of the proposed design.

Awesome! Downward adjustment...who would have thought. Of course, your worries are the same as mine. Thanks for sharing your experience, Marcus. This means so much to the community of struggling young engineers.

Electric motors must meet the requirements in the efficiency table regardless of the location of the project. Keep in mind that there a various exemptions from the efficiency requirements for electric motors. They must be base mounted, single speed, 3 phase, etc..

I Thought I have seen somewhere that the equivalence with the energy Policy Act is that the motors should be at least IE2 class.

Use the area of the conditioned space.

Not all projects will have at least 25% process loads; that number is simply representative of a "typical" amount. If your project has less, indicate through a narrative why that is so. Exceptional Calculation Methods are for claiming savings from the process loads, and are necessary when the percent process load differs between the baseline and proposed models.

I don't think so. Your situation is not really purchased heating or cooling. Neither hot water, nor chilled water is used in the system, it is a heat exchanger.

Thanks for the answer. How should we consider this system in that case? Do we need to take into consideration the other buildings which are using this heat exchanger to the total efficiency of the Central Plant?

I think you would just model the portion of the well field associated with the project in question.

The residential is System 1 or 2. For the office see if G3.1.1 Exception a applies. If so then enter Table G3.1.1A with the office area and fuel type and select the system type. If not the whole building is system 1 or 2.

We vote for 2 as well. The baseline W/GPM should be identical to the proposed.

Not sure about the Canadian system but the form in the US system automatically calculates the proper percentage based on the ratio of new and existing.

Q3) how does Appx G handle system types and space ventilation rates for the baseline where in the proposed design there are only exhaust fans, but with hydronic heating?

Regarding natural ventilation - are you wanting to claim energy saving credit for a natural ventilation system or are you talking about the natural ventilation through operable windows in ASHRAE 62?

Q - Assuming the ASHRAE 62 type of nat vent, you basically model infiltration and no exhaust in most spaces. In the areas with harmful contaminants mechanical ventilation would be required by ASHRAE 62.

Q2 - Ventilation is separate in the baseline if it is separate in the design and you do not model one if you do not have one installed. I think that the requirement to add a system that does not exist in the proposed is just plain busywork. You can always get around it having an effect on your model by adjusting the temperature settings.

Q3 - The baseline system type is still from G3.1.1 and is not based on the proposed air or heating distribution systems. The space ventilation rates still need to be identical.

So are you saying that for a 62.1 Nat Vent compliant model, I should model ventilation rates as zero (oda requirements = zero) and only infiltration (infiltration is what happens when all windows/doors are closed, whereas Natural Ventilation is what happens when you open a window).

If you are saying (and I hope you are not) that I should model Natural Ventilation, then I would say that
1) this can only be believably done using CO2Carbon dioxide and temperature to anticipate user behaviour on a minute by minute bases and that wild temperature swings (especially in winter) will play havoc with unmetloadhours.
2) This model would have to incorporate when users close windows due to too high air change rates (and incorporate wind velocities).
3) The baseline building windows would have to be the same size to allow the same venting possibility, but may not vent the same or at the same time if using the same control algorithms. It would also require that only non-operable windows may be size adjusted to meet the 40% WWR.

How do I know this? Because I have tried on and off over the last 3 years to do this for an exceptional calculation methodology.

Section 6 of 62.1 says "This section is not required for natural ventilation systems;" This will also affect the exhaust requirements for WCs and Kitchens.
In the case of WCs, they WCs don't even need the 4% of net occupiable floor area for window opening area, as the net occupiable floor area is zero (it is not an occupiable space as per the definition in the standard).

It looks like I will be resetting all my ODA requirements to zero.

You said "In the areas with harmful contaminants mechanical ventilation would be required by ASHRAE 62." I don't think this is the case for a naturally ventilated space as they exclude section 6. Could you point me to the relavent section in 62.1 (I know this is a requirement of IAQc5, but I don't find it in 62.1).

The mechanical ventilation rates would be zero if you do not have any mechanical ventilation in the design. You should model natural ventilation since it has an impact on the loads and it should be identical in both cases. You would only need to do the exceptional calculation if you are claiming savings related to natural ventilation.

1) do not schedule the windows to open when outdoor conditions would require the operation of the HVAC systems.
2) yes this would need to be scheduled
3) Good point. Make sure that the operable window area is identical.

That is what happens when you answer a question off the top of your head.

You are correct that 62.1 does not require mechanical ventilation for areas with harmful contaminants.

Our interpretation of occupiable space, based on the definition, would be that WCs are occupiable spaces and therefore require ventilation.

Thanks for your inputs, Marcus. Greatly appreaciated.

Hello Jean, I solved a similar problem working with the control of the radiant floor. It was something similar: during the night the setpoint temperature was 15°C and since the 9.00 the setpoint temperature was 20°C. The problem with the not met sepoint temperatures was during the morning, therefore I anticipated the “diurnal mode” of the heated floor in the last hours of the night (obviously without changing the zone setpoint temperature; the practical way to solve the problem depends on the used software).
Because of the thermal inertia of the heated floor I was able to anticipate the “night mode” in the afternoon.
Probably also increasing (in a reasonable way) the supply water temperature could help.
I don’t know if working with the control system could be useful in your case. Perhaps your problem depends on too high natural ventilation rates, even when there are very cold outdoor temperatures. In that case you should try changing the management of natural ventilation.
I think that the resolution of the problem depends a lot on the used software. Maybe a discussion in the maling list of EnergyPlus could be interesting :-)
Regards

It's a bit more complicated...the culprit rooms are rooms that require per ashrae have high exhaust rate requirements, like a kitchen or WC. The makeup air is currently comming from outside...perhaps the solution is to have the makeup air come from adjacent rooms and setting the AHU1.Air-handling units (AHUs) are mechanical indirect heating, ventilating, or air-conditioning systems in which the air is treated or handled by equipment located outside the rooms served, usually at a central location, and conveyed to and from the rooms by a fan and a system of distributing ducts. (NEEB, 1997 edition) 2.A type of heating and/or cooling distribution equipment that channels warm or cool air to different parts of a building. This process of channeling the conditioned air often involves drawing air over heating or cooling coils and forcing it from a central location through ducts or air-handling units. Air-handling units are hidden in the walls or ceilings, where they use steam or hot water to heat, or chilled water to cool the air inside the ductwork. for these spaces to circulation only. I'll give it a go.

Actually, thermodynamically it makes little difference where the extra ODA is heated, and for the additional effort, I think I'll just include the 2nd system for now.

Just an update...as the real ODA requirement for my tested WC is zero, I have found that giving the system 3 cooling system a outdoor air requirement of zero, whilst simultaneously pulling the make up air of the required exhaust rate from the adjacent space seems to solve my problem.

The EIR value is the only thing in the SV-A report that addresses the break out of fan power. Perhaps the issue is not using the eQUEST default calculation. So keep fixating.

You would model a gas hot water heater in the baseline and you'd model the proposed as designed.

A slight amendment to Anthony's suggestion - model the baseline for the heat pumpA type of heating and/or cooling equipment that draws heat into a building from outside and, during the cooling season, ejects heat from the building to the outside. Heat pumps are vapor-compression refrigeration systems whose indoor/outdoor coils are used reversibly as condensers or evaporators, depending on the need for heating or cooling. In the 2003 CBECS, specific information was collected on whether the heat pump system was a packaged unit, residential-type split system, or individual room heat pump, and whether the heat pump was air source, ground source, or water source. as electric water heater and the baseline for the boiler as gas water heater.

The solar is all savings!

Anthony,

We had the same question as Fabiano's a few days ago and we found in ASHRAE 90.1-2007, Appendix G, 11-Service Hot-Water Systems that:

"The service hot-water system in the baseline building shall use the same energy source as the corresponding system in the proposed design..."

So we concluded we had to model the solar water heating system in the baseline. I'm confused now...

Solar hot water is considered "on-site renewable energy" and should be modeled in the proposed only, as it is a savings. Report the savings in the appropriate section in the EAp2 template. you should be good to go!

Thanks,

I am going considering the heat pumpA type of heating and/or cooling equipment that draws heat into a building from outside and, during the cooling season, ejects heat from the building to the outside. Heat pumps are vapor-compression refrigeration systems whose indoor/outdoor coils are used reversibly as condensers or evaporators, depending on the need for heating or cooling. In the 2003 CBECS, specific information was collected on whether the heat pump system was a packaged unit, residential-type split system, or individual room heat pump, and whether the heat pump was air source, ground source, or water source. (electrical) and the boiler (gas) for the baseline.

The solar will be the savings for the Proposed then.

I can't find any LEED Interpretations on the subject, but I've always handled DHWDomestic hot water (DHW) is water used for food preparation, cleaning and sanitation and personal hygiene, but not heating. systems similarly to HVAC system types. So for example, if the proposed building had a hybrid (gas/electric) HVAC system, you would use gas in the baseline. Similarly, if my proposed DHW system is a hybrid, I would use gas in the baseline. I agree that the user's manual doesn't really clarify this issue, so my guess is that either approach would be acceptable to GBCI.

The GBCI reviewer will follow the guidance in Table G3.1-11 Baseline that was quoted by Marcio above for the baseline service hot water (SHW) systems. "The service hot-water system in the baseline building shall use the same energy source as the corresponding system in the proposed design..." This language is pretty clear. SHW does not follow the same baseline guidance as the HVAC systems.

The solar hot water is addressed by the Exception to G2.4 which indicates that you use the back up source for the baseline when using an on-site renewable in the Proposed.

You're right, I started reading at bullet "a" which wasn't helpful.

According to Table G3.1.10 , you have to simulate, even if no cooling and heating system exist in building. In this case your baseline case and Proposed case HVAC system will be similar.

In your case if your building is residential than your baseline system will be System 2, if it is commercial than your baseline system will be system 4. For proposed case you have to use similar system that you have used for Baseline case.

Basic fundamental behind similar system is that you can show saving from envelop, lighting, HWH (if your envelop, interior lighting is more efficient than baseline) .

Hope this info helps you.

Good luck

Thanks Anil!

1. I am not sure of the T24 rules but it certainly makes sense to not model systems that do not exist and are identical. Even in 90.1 there is a work around to the requirement that Anil mentions - just change the temperature settings so the fake systems do not run.
2. No you do not.
3. Implement lighting and service hot water saving measures! Are you claiming any hot water demand reduction?

Thanks for the response Marcus!
1. We attempted to fake the systems with the temperature set points, however this apparently is not possible in EnergyPro. We ended up discussing this with EnergySoft who confirmed this would not be an option.
2. Thank you for confirming. This is good news.
3. I have a note to confirm that we are claiming hot water demand reduction, however am unsure right now. We are seeing some savings from the service hot water and may be able to capture some additional savings by switching to a more efficient unit. Lighting has been the Achilles heel for the project. From the beginning we were counting on efficient lighting to pull us through and achieve the minimum 10% savings, then the County requested additional lighting for safety measures and we are back to the drawing board with little room to work (without adding additional energy usage).

The standard is intended to regulate mainly conditioned spaces. IMO if the space is not conditioned, it has no "real" setpoint to meet. So the heating setpoint could be -50 deg C and the cooling setpoint could be +100 deg C. I have no problem with this for unconditioned spaces, unless they are regulary occupied...in which case I believe the intent of the standard is to anticepate that dissatisfied users will retrofit conditioning systems if they are often dissatisfied. For naturally ventilated spaces the upper bounds could be 28-32 deg C and the lower bounds at say 15 deg C. Check out AM10 to back up wild claims like this.

There are no envelope requirements for unconditioned spaces, meaning baseline = designcase. It's going to be hard to show enough savings.

Thank you Jean, I appreciate the suggestion to look at AM10. The project is located near the ocean in Southern California and the occupied portion is essentially a concession area which will serve the public at a park with a water fountain / feature. A majority of the time the weather in this area does fall between 15 and 32 deg C, and the concession area will likely not be open if it is below 15 deg C. There may be 2 times a year when the temperature is above 90 degrees F this close to the ocean.
I agree that it is going to be difficult to show enough savings as currently designed. We have discussed including AC in the building to take advantage of energy savings from the envelope and AC ...however it seems counterintuitive to include AC in a building to achieve energy savings for LEED. If we thought that thermal comfort was a real concern it would be a different story. I think that going back to the owner and discussing the lighting one more time may be appropriate, however I wanted to make sure that we would not run into problems with unmet hrs before asking for design changes. Alternatively, maybe looking into the thermal comfort and pursuing savings via exceptional calculations for natural ventilation is appropriate?

Re: via exceptional calculations for natural ventilation
In my experience, unless you have moterized automatic window/vent control to fractionally modulate the openings, regulating the temperature and or room air quality with windows/vents is very hard to proove with a simulation program.

I am currently attempting to do so (i.e. mimick building user behaviour for opening and closing windows) and it is very time intensive and shows pretty erratic behaviour. Especially in winter, due to cold outdoor temps, the room air temperature swings are huge. In 10 min the temp can drop from 22 degC to 17 deg C by opening windows when it is -2 outside. Wind plays a role, air speed plays a role, air quality plays a role.

This particular project has huge internal mass and internal gains, meaning even without heating, the zone overheats in winter if the windows remain closed. If you open a window the room overcools quickly, and as soon as you close the window, it overheats just as fast. I'm having to split the windows in each zone into 2 groups to "modulate" the total opening area (as windows have at most just 3 settings (closed, open, tip).

And I'm still testing and tuning...

If you go this route, good luck.

I suggest doing the baseline AC in both models (where none are planned).

You do not have to follow the addendum, they are all optional. Looks like the base site lighting power replaced the additional 5% allowance, so yes you can add it.

What software are you using?

trace 700

I am also creating baseline with system-6. For system i have selected FP VAVVariable Air Volume (VAV) is an HVAC conservation feature that supplies varying quantities of conditioned (heated or cooled) air to different parts of a building according to the heating and cooling needs of those specific areas. with reheat, than for FP vav box, I took 50 % of Total CFM (Cooling) and multiply 50 % of CFM by 0.3 to get wattage. And input total wattage into secondary supply fan in Fan tab.
After reading above comment it sounds like, it is more complicated than what i did.

Any suggestion?

Thank you

Just to be clear the value is 0.35 W/cfm.

We are not aware of any limitations in Trace for accurately modeling this issue. Anil's approach sounds right to us but we are not Trace experts. Consult the help desk again or post your issue on the Trace users group at onebuilding.org. Any other thoughts?

thanks Marcus and Anil that's easy way of doing it.

You must include the pool. Check to see if some components of the pool heating are regulated by 90.1 in Section 7. If it is then it is not process. How you model it depends on the capabilities of the software you are using.

If they are truly identical, including orientation,etc. then you would only have to do one. Are they all part of one LEED project? Are you looking a the LEED Volume Program?