outdoor reset control theory full versus partial reset• it almost always makes sense to use these...
TRANSCRIPT
Supp
ly wa
ter t
empe
ratu
re (º
F)
70
110
150
190
Outdoor temperature (ºF)70 60 50 40 30 20 10 0
170
130
90
60
heat source on
heat source off
140
this portion of !reset line not used
target temperature
210
190 ºF
Outdoor Reset Control TheoryFULL versus PARTIAL reset
Conventional boilers must be protected against sustained operation at low water temperatures. If not, they will be damaged by sustained flue gas condensation.
The blue line shows partial reset control for a conventional, gas-fired boiler. The supply water temperature is not allowed to go below a target of 140 ºF, regardless of how warm it is outside.
Supp
ly wa
ter t
empe
ratu
re (º
F)
70
110
150
190
Outdoor temperature (ºF)70 60 50 40 30 20 10 0
170
130
90
60
140
target temperature!(boiler outlet)
210
190 ºF
105 ºF
target temperature!(mixing valve outlet)
VENT
combined boiler + mixing reset controller
boiler supply temperature!
sensor
boiler inlet temperature!
sensor
mixed supply temperature!
sensor3-way
motorized mixing valve
conventional boiler
Outdoor Reset Control TheoryFULL and PARTIAL reset in same system
Outdoor Reset Control TheoryCompensation for non-proportional heat loss/gain(parallel shifting)
Tbalance = Tindoor –
Qgain
UA building
70
80
90
100
110
120
70 60 50 40 30 20 10 0 -10
Wat
er s
uppl
y te
mpe
ratu
re (º
F)
Outdoor temperature (ºF)
60
80
60
starting point line
parallelshift
starting point (moves along starting point line)
Tstart =Tinside + R×Tbalance( )
1+ R( )outdoor reset controllers with indoor temperature sensors will automatically parallel shift the reset line based on internal gains or losses.
Instantaneous Domestic Water HeatingFrom Thermal Storage Tanks
Starting points:
• Most of these systems use water for thermal storage.
• Nearly all thermally-based renewable heat sources require significant heat storage.
• Solar thermal system• Geothermal heat pump systems• Wood- and pellet-fired boilers
• Even low storage tank temperatures are useful for preheating domestic hot water.
• Keeping all portions of the DHW system outside the thermal storage tank has several benefits.
• Hydronic based instantaneous domestic water heating has been used in thousands of European installations .
• It almost always makes sense to use these heat sources to provide domestic hot water, as well as space heating.
• Modulating electric tankless water heaters have some distinct advantages in dealing with preheated water.
• Brazed plate stainless steel heat exchangers are readily available and have very fast response times.
air vent!w/ shut off
valveso
lar co
llector
array
solar!circulation!
station
check!valve
DHW
CW
solar storage tank!(dual coil)
relay
mod
/con
boi
ler
make-up water
AB 3-way !diverter !valve (D1)
A B
(P1)closely spaced tees
outdoor!temperature!
sensor
(P2)
pressure- regulated circulator
space-heating circuits!(highly zoned)
heat source!circulator
!anti-scald!tempering !valve
relay (R1)
manifold valve actuator
thermostat!(1 per zone)
end
switc
h le
ads
3-way!motorized!
mixing!valve!(C2)
end switch leads from actuators
P&TP3
One way to make a solar combisystem...Drawbacks: • Top of thermal storage has to be maintained at suitably high temperature for domestic hot water delivery - reduces collector efficiency.
• Space heating from storage may be significantly limited by capacity of upper internal coil in storage.
Another way to make a solar combisystem...
DHW coil
PRV
All solar circuit piping sloped minimum
1/4" per ft.
sight!glass
static water level
lift
head
AB
3-way!diverter!valve
A B
heat source!circulator!w/ check
storage / drainback tank
air space
air return!tube
differential!temperature!
controller
3-way mixing valve
closely spaced tees
solar!collector!
array
collector!circulator
auxiliary boiler
space heating!distribution!
system
air return tube
cold water
hot water
3-way mixing valve
outside temperature
sensor
Pressurized drainback system w/ internal coil for domestic water heating.
• Passive domestic water preheating• Boiler maintains temperature at top of storage.• Thermal mass of tank buffers space heating load.• Single tank simplicity
• Sourcing the tank may be an issue• Internal coil may be difficult or impossible to service
!loading!
unitpressurized thermal storage tank
wood-fired boiler
bypa
ss
air vent
temperature sensor well
Wood gasification boiler with heat storage.
Large thermal storage is often used with wood gasification boilers.
VENT
buffer tank
temperature!sensor
to / from other heating
zones
variable-speed!pressure-regulated!
circulator
outdoor!reset!
controller
low temperature distribution system
water-to-water!heat pump(heating only)
Comp.
cond
ense
r
evap
orat
or
compressor
TXV
geothermal manifolds
earth loop circuits
purging!valves
Geothermal heat pump space heatingwith heat storage.
make up water
buffer tank
OUTS
IDE
INSI
DE
air to water heat pumpflow switch
pressure regulated!variable speed
circulator
manifold valve
actuators
zoned radiant ceiling panels
outdoor!temperature!
sensor
outdoor!reset controller
antifreeze!protected!
circuit
Air-to-water heat pump with heat storage.
gas or propane supply
hot water
cold water
premix gas burner
outlet!temperature !
sensor flow sensor
heat exchanger
controller
ASSE 1070 mixing valve
inlet!temperature !
sensor
isolation &!flushing valves
Gas-fired tankless water heaters and preheated water• Many gas-fired tankless water heaters have limited modulation ability.• Most require an inlet temperature at least 20ºF lower than their setpoint as a condition to fire their combustion system.
IF Qthermal ≤ QHTmin THEN burner doesnʼt fire
Where:Qthermal = current thermal load on heater (Btu/hr)f = flow rate through heater (gpm)Tseptoint = desired water outlet temperature leaving heater (ºF)Tin = water inlet temperature to heater (ºF)QHTmin = minimum rate of heat transfer to water (Btu/hr)Qgas = minimum gas input rate to burner (Btu/hr)n = combustion efficiency of burner / heat exchanger (decimal %)
Thermal load on heater:
Minimum heat transfer rate of heater:
Because Qthermal ≤ QHTmin THEN burner doesnʼt fire
Thermal load on heater:
Minimum heat transfer rate of heater:
gas or propane supply
hot water
cold water
premix gas burner
outlet!temperature !
sensor flow sensor
heat exchanger
controller
ASSE 1070 mixing valve
inlet!temperature !
sensor
isolation &!flushing valves
Assume the minimum gas input to a tankless heater is 10,000 Btu/hr, and the combustion efficiency is 90%. Solar preheated water enters the unit at 110 ºF and 0.8 gpm. The setpoint of the heater is 120 ºF. If the controller in the unit operates as described on previous slide, will the burner fire under the stated conditions?
This works - BUT...
It also lowers the “net” preheating effect supplied by the solar subsystem.
For example: Assume the setpoint of the tankless heater is 120 ºF. Solar preheated water arriving at the tankless heater at 110ºF would have to be mixed down to 100 ºF before entering the heater. Assuming a desired delivery temperature of 120ºF and a cold water temperature of 50 ºF, this 10 ºF mix down decreases the solar supplied portion of the water heating load from 86% to 71%.
One “work around” is to mix down the inlet temperature using a second thermostatic valve.
hot water
cold water
thermostatic MIX DOWN valve!(set 20 ºF lower than setpoint of heater)
preheated
water
One “work around” is to mix down the inlet temperature using a second thermostatic valve
European product by
Caleffi
Another option is to divert water around the tankless heater if temperature is above a specified setting.
hot water
cold water
electric diverter valve
solar preheated
water
PRV
Thermostatically controlled electric tankless water heaters
Typical “point of use”ETWH 3-6 KW
Typical “whole house”ETWH 10-40 KW
20KW unit
maximum possible water temperature rise always depends on flow rate
contactor
relay coil contacts
flow switch
electronics (PCB)
overtemp switch
element enclosure
240VAC input
setpoint adjustment
12KW unit, 50Amp / 240VAC
COLD
in
HOT
out
ETWH
hot water
cold water
isolation &!flushing valves
inlet!temperature !
sensor
heating!element
outlet!temperature !
sensor
flow !sensor
controls
240 VAC !electrical supply
PRV
Thermostatically controlled electric tankless water heaters
Amps = KW0.24
Thermostatically controlled electric tankless water heatersElectric tankless water heaters are HIGH AMPERAGE devices.
Minimum 200 Amp breaker panel recommended.
23 KW Requires TWO, 50 amp /240VAC breakers
3.5 KW Requires 15 amp / 240VAC breaker
May be an issue in some older retrofits.
Thermostatically controlled electric tankless water heaters
ETWH
hot water
cold water
isolation &!flushing valves
inlet!temperature !
sensor
heating!element
outlet!temperature !
sensor
flow !sensor
controls
240 VAC !electrical supply
PRV
Thermostatically controlled electric tankless water heaters use a TRIAC to vary the wattage to their heating elements from 0 to 100%.
They can therefor handle situations where preheated water needs a small temperature “boost” without short cycling.
gates for TRIACS
from heat!
source
to heat!
source
space heating!supply
space heating!return
air vent
temperature!sensor(s)
small circulator
with check valve
flow switch
space heating!supply
ASSE 1017 !anti scald !
mixing valve
hot water
cold water
stainless steel heat exchanger
from storage
return to storage
electric tankless!water heater
space heating!return
HX flushing!valves
Instantaneous DHW subassembly
flow switch
ASSE 1017 !anti scald !
mixing valve
hot water
cold water
electric tankless!water heater
buffer tank
pressure-regulated!variable speed
circulator
1/2" PEX or PEX-AL-PEX tubing
TRV
flow switch
ASSE 1017 !anti scald !
mixing valve
hot water
cold water
electric tankless!water heater
Instantaneous DHW subassembly• Leverages the thermal mass for stabilizing DHW delivery.
• Brazed plate heat exchanger provides very fast response (1-2 seconds)
• Fully serviceable heat exchanger (unlike an internal coil heat exchanger) Can be cleaned or replaced if necessary.
• Predictable heat exchanger performance
• Very little heated domestic water is stored (reducing potential for Legionella growth).
• Very low wattage circulator needed on primary side of heat exchanger
Instantaneous DHW subassembly
Brazed plate stainless steel heat exchangers are widely available.They have very high ratio of surface area to volume.
Response time to quasi steady state = 1 to 2 seconds
3”x5”
5”x12”
10”x20”
Response time of this subassembly is likely under 5 seconds.(assuming short, insulated piping b/w HX and storage tank)
<= 10 ºF
domestic water
maximum suggested!approach temperature!
difference
from!storage!
tank
http://flatplateselect.com
Sizing the brazed plate heat exchangerSuggest a maximum approach temperature difference of 10 ºF under max. anticipated water demand, and minimum preheat inlet temperature.
FG5x12-305” wide x12” long -30 plates
from heat!
source
to heat!
source
space heating!supply
space heating!return
air vent
temperature!sensor(s)
small circulator
with check valve
flow switch
space heating!supply
ASSE 1017 !anti scald !
mixing valve
hot water
cold water
stainless steel heat exchanger
from storage
return to storage
electric tankless!water heater
space heating!return
HX flushing!valves
Instantaneous DHW subassembly
B&G Vario circulator operating at 33 watts yields10 gpm as required to raise 4 gpm of water from 60 to 110 ºF through FG5x12-30 heat exchanger supplied by 120ºF water from thermal storage.
To deliver 60 gallons per day at average draw rate of 2 gpm, this circulator would operate for 30 minutes, and consume 0.0165 KWHR. Operating cost of this circulator would be $0.78 per YEAR.
hot water
cold water
to / from!space!
heating
internal!circulator
motorized!diverter!valve
stainless steel!brazed plate!
heat exchanger
anti-scald!valve
flow!switch
combi-boiler
Other tankless water heater options
Response time from cold start to near steady state at delivery temperature (20-30 seconds)
combi-boilergas-fired tankless
All gas fired equipment needs gas supply, venting,and electrical connections
flow switch
stainless steel !heat exchanger
to / from!other loads
HX flushing valves storage tank!(with varying temperature)
hot water
cold water
!mixing valve
electric tankless!water heater
to /
from
hea
t so
urce
(s)
swing check valve
circulator with check valve
circulator with check valve
Instantaneous DHW subassembly piping
NOTE: Check valve required on tank-to-HX circuit to prevent reverse flow during space heating
thermostatically!controlled ETWH
240 VAC !electrical supply
relay!240 VAC coil!
in junction box
17
4
28
5
39
6
AB
120 VAC
N
storage to!HX circulator
PRV
Contactor inside Eemax EX012240Textra terminal on coil circuit of contactor
Using extra terminal on ETWH contactor to operate circulator
This eliminates the need for the flow switch.
flow switch
from storage
return to storage
thermostatically controlled!tankless electric!water heater
set for 130 ºF
DHW
cold water
insulated piping
set for max 120 ºF
Add 2nd thermostatic valve if the high limit switch canʼt be set higher than 140 ºF.
Why not just use internal heat exchanger coils?These are all examples of European multi-coil thermal storage tanks.
Why not just use internal heat exchanger coils?• These tanks cost over $4000
• What happens when a pinhole leak develops anywhere inside the tank?
•Internal coils are limited by natural convection heat transfer.
•No one offers tanks like this in North America
• Many European tanks - even if available in North America, may not meet codes (ASME).
This concept is already being used...
Thermal energy substations in European flats
Parting thoughts... 1. Keep it neat...
Parting thoughts... 2. Recognize opportunity...
Parting thoughts... 3. Donʼt get hung up...
Thank you for attending today’s session...
www.hydronicpros.com
Please visit our website for more information (publications & software) on hydronic systems:
Thanks also to the planning committee, and the sponsors of this session.
"Best Practices in Modern Hydronic Heating - THE DETAILS