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m_display_main.jpg | ||
m_ds18b20_epoxy.jpg | ||
m_ds18b20_evaporator_mount.jpg | ||
m_ds18b20_wires_protection.jpg | ||
m_HeatPump_scheme2.png | ||
m_plate_echangers_oxygen_brazing.jpg | ||
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README.md |
Valden Heat Pump Controller v1.x
The Valden Heat Pump controller is a platform to precisely control heat pumps. This controller can be used for the automation of newly created Heat Pumps (HPs), as a repair controller for old systems or as control system for performing experiments on refrigeration equipment.
Specs
- 12V 0.5A DC power supply,
- 230V output,
- 4 16A relays: Compressor, Hot Circulating Pump (CP) or Air Fan, Cold CP or Air Fan, Crankcase Heater,
- 2 inputs: Hot and cold side refrigerant over/under pressure NC sensors,
- up to 12 temperature (T) sensors, -55..+125 °C range,
- Electronic Expansion Valve (EEV) supported, 6 pin EEV connection: 4 * coils + 2 * 12V,
- automatically turns on/of system when heating required,
- automatic power saving mode,
- built-in protections: cold start, overheat, short-term power loss, power overload, ground loop freeze, compressor protection against liquid and other,
- LED indication,
- control via remote display or local Serial (UART 5V),
Refrigeration schemes supported
- Heat Pump (HP) with Electronic Expansion Valve (EEV),
- HP with capillary tube or TXV,
- EEV-only controller.
Installations supported
- Indoor: a house or technical building with an almost stable temperature,
- Outdoor: harsh climatic conditions taken into account. Outdoor HP installations tested down to a minus 32 °C.
Changelog and history
- 2018: PCB prototype, first real installation,
- 2019: 2-layer PCB, through-hole components, integrated buttons and display,
- 2019: controller redesigned taking into account development and operating experience, 2-layer PCB, SMD,
- 2019-2021: installations, development, tests, revisions, redesigns,
- 06 Feb 2021: product is technically completed and ready for public access. Documentation and release stage.
Get your own PCB copy. Assembly.
- download PCB Gerber file or get your own copy {-link here-}
- order electronic components, see BOM (Bill Of Materials) appendix below,
- solder electronic components. {- assembly instructions here-}
Firmware upload
This process is the same as for other Arduinos:
- connect USB-> UART converter,
- start Arduino IDE,
- open the firmware {-link here-} file,
- select board and MCU in the Tools menu (hint: we are using "mini" board with 328p MCU),
- press the "Upload" button in the interface and "Reset" on the Arduino.
For arduinos with an old bootloader you need to update it. (Tools-> Burn Bootloader).
For successful compilation, you must have "SoftwareSerial", "OneWire" and "DallasTemperature" libraries installed (see Tools -> Manage Libraries).
For the first time it's enough to upload firmware without any tuning. Think of it as of a commercial closed-source controller, where you cannot fine-tune internal options. And any other manual configuration do not required too, just upload firmware.
Self-tests
QA tests are available to test the assembled board.
Self-test helps you check relays, indicators, speaker and temperature sensors.
To run a self-tests:
- uncomment this 3 defines in source code header,
//#define SELFTEST_RELAYS_LEDS_SPEAKER //speaker and relays QA test, uncomment to enable
//#define SELFTEST_EEV //EEV QA test, uncomment to enable
//#define SELFTEST_T_SENSORS //temperature sensors QA test, uncomment to enable
- upload firmware,
- connect 12V power supply.
Video {- demostration "How self-tests works":-}
To check EEV, you can use a stepper motor as shown in the video. If you are testing a real EEV, it should be closed after the first "beep" and partially opened after the second "beep".
To check temperature sensors connectors prepare one array of sensors. Plug it to all sensors connectors one-by-one and check results in a serial console.
{-Photo: PCB with connected arrays of sensors (I have enough sensors, so all 3 arrays are connected except Ts2 and Treg) -}
{-Screenshot: serial console with temperature readings: -}
Wiring
Wiring is very simple despite the many connections:
Phases (1st wire in electrical cables):
- connect the "power inlet" wire to one of the "phase" terminals,
- and connect the second "phase" terminal to the AC input of the 12V power supply,
- connect the "Compressor" relay output to the Compressor input,
- connect the "Hot CP" relay output to the Hot Circulation Pump input (or to the fan power input of the indoor unit if you are using an air system),
- connect the "Cold CP" relay output to the Cold Circulation Pump input (or to the fan power input of the outdoor unit air fan),
- when using a compressor heater: connect the "Crankcase heater" relay output to the heater cable (highly recommended for outdoor installation and year-round use). Neutral (2nd cable in electrical cables),
- connect all the second wires of power cords to the "neutral" terminals on the board.
{-Photo of HV connections-}
Crimp and plug low-voltage connectors:
- SCT013 sensor (the only one low-voltage device in the circuit with interchangeable contacts), connect and install it on the inlet phase wire,
- RS485 to the Remote Display, using a wire of desired length (note that A is connected to A, B to B and GND to GND),
- 12V and GND secondary terminals to the remote display,
- EEV to EEV terminal,
- insert T sensors arrays appropriate terminals,
- crimp and plug pressure sensors outputs: crimp 1st wires together to the right terminal, 2nd cold side wire to the left terminal, 2nd hot side wire to the middle terminal; use the dummy if no pressure sensors used in your system.
You may prefer to solder the wires over using connectors. But in this case, it will be difficult to disassemble the system if you want to change something. The choice is yours.
{-Photo: T sensors with abbreviations and full names-}
{-Photo: RS485 and 12V power for display-}
{-Photo: all together-}
And one more: remember! 230V inside! Do not turn on the phase without need.
Have you ever received 230V with your own hands? If yes - you know. If no - do not try.
Also remember about animals and children during the installation at a permanent place.
Sensors mount
{-Sensors scheme-}
{-Photo: power wire + SCT013-}
{-Few photos: DS18B20 sensor installed -}
{-Photo: pressure sensors installed -}
{-Photo: pressure sensor dummy -}
Control and usage: serial console
This is a first interface to Heat Pump controller you'll see after uploading firmware (Tools->Serial Monitor).
The console itself is simple to use, several commands are available. Type in command, press "Send". Help and hotkeys:
Every HUMAN_AUTOINFO times you'll see stats. For example, after a startup of your compressor, you'll see something like this:
At this example, "hot in" ~30 °C, compressor ~80 °C and so on. Heat Pump (HP, compressor) ON, Hot water pump ON, Cold water pump ON. Power consumption 980 watts.
Abbreviations: refer to Appendix A below.
And you'll see diagnostic messages in the serial console.
Control and usage: remote control display
This is a way for the end user to control Heat Pump.
End user does not want to know much about refrigerants, evaporation, discharge temperatures and so on, so this display designed as simple as it was possible. See display page for details. And yes, this display is open product too, with available Gerber, PCB and source code.
Control and usage: service display
One day I've realized that a netbook with a serial console is a good diagnostic tool, but I want a compact tool to get maximum available information from a Heat Pumps. So, this "Quickly Assembled Service Display" appeared. It fits everywhere and with a good power bank it can work 2-3 days long, without any additional power source. The diagnostic display is build from scratch, no PCB and housing here (and no plans to create it), because I do not see this service display as a permanently mounted device.
If you want a compact and visual tool - this device is for you, so check the Service Display Page .
Starting up the heat pump system for the first time and charging refrigerant
This is an easy part, but if you don't have experience it will take time.
You have performed a pressure test and vacuuming. It's time to charge your system.
Let's say you don't know how to calculate the amount of refrigerant in a recently built system, so follow next steps:
- charge a small amount (for example 300 g) of refrigerant,
- get ready for a system protective stops by Tae or Tbe temperature, this is a normal system behavior while refilling refrigerant,
- power on your heat pump,
- after compressor startup suction temperature will be about -20 ...- 40 °C (according to the suction pressure on the pressure gauge),
- for single-component refrigerants: slightly open the valve of the HVAC gauge manifold and start adding refrigerant through the gas phase on the cold side,
- for multi-component refrigerants: turn over the refrigerant cylinder, VERY SLIGHTLY open the HVAC manifold valve and start adding VERY LITTLE amounts through the liquid phase,
- continue, until the suction temperature (according to the suction pressure on the manometer) is ~ 10 ... 12 °C lower than the temperature of the heat source (example: the temperature at the inlet of the mixture of water and antifreeze from the closed ground loop is + 8 °C, so the suction temperature should be -2 ..- 4),
- close the manifold valve,
- at every step check the discharge pressure: it should not be above the discharge sensor temperature (Tbc),
- wait for the system to heat the target to an almost stable temperature, add little amounts of refrigerant while temperature increases (and suction decreases),
- stop if you are sure that the heating process proceeding slowly,
- take a final look and charge when the system is stable and the heat pump stops normally (setpoint is reached), this may take 12 hours or more,
- after the final refilling difference between the suction pressure temperature and the Tae sensor temperature should be 3 ... 6 °C.
This algo is good and safe both the first time and as a starting point. As you gain experience, you will get yours much easier and faster.
Also, use "manual EEV mode" during refilling process.
Hints
For more information about Heat Pumps look at Wikipedia HP page.
If you want to know "how the refrigeration systems work", read Patrick Kotzaoglanian books.
If you want more technical details, sophisticated schemes, "how EEV can be driven by temperature" diagrams, etc. refer to vendor manuals (you'll find all you need in the Alfa Laval brochures, Danfoss guides, and so on).
For refrigerants and oils types comparison see wiki.
Personal experience
Note that the SCT013 sensor and the current monitoring scheme cannot be used for accurate measurements and accurate COP calculations. Use a watt meter for accurate power measurements.
Temperature sensor installation at a warm floor surface point is a bad idea - it's better to get "hot in" water temperature coming from all over the floor, as implemented in firmware.
The weather-dependent (both outdoor and indoor temperature dependent) system does not work fine for 30-150 m2 buildings. Such a system is too complex and works unpredictable due to random ventilation. And also due to the unpredictability of heat emitted in the house by other sources.
I tried the scheme with a flooded evaporator in 2019 and found it terribly tricky, then refused to use it.
Deep regeneration schemes are useful only for some refrigerants and only in certain temperature ranges. I've tried deep regeneration too. As a result, the theory coincided with practice and I also refused this idea.
In general, it is possible by complicating the refrigeration scheme to win somewhere 1%, somewhere 3%, but all this leads to significant time and money cost getting suddenly a small profit.
Summary: If you want experiments - Experiment. Want reliably - make the system simple.
License
GPLv3.
This product is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
Author
gonzho АТ web.de (c) 2018-2021
Appendix A: Abbreviations
Abbreviations used in the documentation and firmware.
Main sensors:
Abbr. | Full name |
---|---|
Tae | after evaporator |
Tbe | before evaporator |
Tci | cold side "input" |
Tco | cold side "output" |
Tbc | before condenser |
Tac | after condenser |
Thi | hot side "input" |
Tho | hot side "output" |
Tcrc | crankcase (compressor itself) |
The additional sensor used in "swimming pool heater" or "water tank heater" schemes, check SETPOINT_TS1 option:
Abbr. | Full name |
---|---|
Ts1 | additional sensor1 |
Additional sensors, disabled and not used by default:
Abbr. | Full name |
---|---|
Treg | regenerator temperature |
Ts2 | additional sensor2 |
Relays:
Abbr. | Full name |
---|---|
RCRCH | crankcase heater relay |
RC | cold side water pump relay |
RH | cold side water pump relay |
RP | heat pump (compressor) relay |
Other:
Abbr. | Full name |
---|---|
LSM | LastStopCause |
LSC | LastStartMessage |
CWP/CCP | cold side water (circulating) pump |
HWP/HCP | cold side water (circulating) pump |
EEVP | EEV position |
HP | heat pump |
Appendix B: Diagnostic and status messages
LastStopCause (LSC) messages. Why the compressor has stopped working.
Message | description |
---|---|
Normal_stop | Normal stop, i.e. setpoint sensor temperature > setpoint, so heat not needed. |
P.WtMax:WATTS | Protective stop. Overcurrent, double-check your system, then MAX_WATTS and POWERON_HIGHTIME options. |
P.W.wattMIN | Protective stop. Abnormally low power consumption (<max watts/5). Check your system, see MAX_WATTS option. |
P.W.TcrcMIN | Protective stop. Abnormally low "Compressor" temperature. Check your system, see T_WORKINGOK_CRANKCASE_MIN option. |
P.Tho | Protective stop. "Hot out" temperature is too high. Check your system, see T_HOT_MAX option. |
P.Thi | Protective stop. "Hot in" temperature is too high. Check system, see T_HOT_MAX option. |
P.Tcrc | Protective stop. "Compressor" temperature is too high. Overheat protection. This is an ordinary situation during long runs. See T_CRANKCASE_MAX option and compressor manual if you want to tune it (~115 °C for wide-available compressors). |
P.Tae | Protective stop. "After evaporator" temperature too low. Preventing cold loop from freezing and protecting suction line from liquid. See T_COLDREF_MIN option. |
P.Tbe | Protective stop. "Before evaporator" temperature too low. Preventing cold loop from freezing. See T_BEFORE_EVAP_WORK_MIN option. |
P.Tbc | Protective stop. "Before condenser" temperature is too high. Overheat protection. This is an ordinary situation during long runs. See T_BEFORE_CONDENSER_MAX option. |
P.Tci | Protective stop. "Cold in" temperature is too low. Preventing cold loop from freezing. See T_COLD_MIN option. |
P.Tco | Protective stop. "Cold out" temperature is too low. Preventing cold loop from freezing. See T_COLD_MIN option. |
E.Tci, E.Tco, E.Tbe, E.Tae, E.Ts1, E.Ts2, E.Tcrc, E.Treg, E.Tac, E.Tbc, E.Tho, E.Thi | Sensor lost, check wiring. Refer to "T sensor abbreviations". |
E.PresCold | Cold side pressure too low, check refrigerant charge and pressure sensors. |
E.PresHot | Hot side pressure too high, check refrigerant charge and pressure sensors. |
LastStartMessage (LSM) messages. What event system is waiting for. Some informational messages.
Message | description |
---|---|
StCntd:seconds | Startup countdown, short-term power loss protection. |
HP_Started | Normal start. |
#Thi>Setp. | "Hot in" temperature > setpoint, so no reason to start. |
#Ts1>Setp. | "Ts1" temperature > setpoint, so no reason to start, see SETPOINT_TS1 option to switch betwees Thi and Ts1 as setpoint sensor. |
HWP_OFF | Setpoint sensor temperature > setpoint, so after some time (HOTCIRCLE_STOP_AFTER option) hot side pump powered off and gone to power saving mode. |
HWP_ON_by_ev | Hot side pump started after power saving. See HOTCIRCLE_START_EVERY option. |
#HotPrp:seconds | Hot side pump is on, waiting for T stabilisation. Countdown, seconds. See HOTCIRCLE_CHECK_PREPARE option. |
#HotSlp:seconds | Hot side pump in power save mode (sleeping). Waiting for next startup. Countdown, seconds. See HOTCIRCLE_START_EVERY option. |
#HPSlp:seconds" | Compressor: pause between starts. Countdown, seconds. MINCYCLE_POWEROFF option. |
#CPpStart | Cold side pump started. |
#CPp:seconds | Cold side pumping. Preparing system to start compressor. Countdown, seconds. COLDCIRCLE_PREPARE option. |
#Tho>Max | "Hot out" temperature is too high. See T_HOT_MAX option. |
#Thi>Max | "Hot in" temperature is too high. , see T_HOT_MAX option. |
#CaseCold | Compressor crankcase temperature is too low. Can't start. This situation occurs if the outdoor installation when AC power was lost for a few hours. Wait, while the crankcase heater stabilizing your compressor temperature. See T_CRANKCASE_MIN option. |
#CaseHot | Compressor is still overheated, waiting. See T_CRANKCASE_MAX option. |
#Tae<RefMin | "After evaporator" temperature too low. Preventing cold loop from freezing and protecting suction line from liquid. See T_COLDREF_MIN option. |
#Tbe<RefMin | "Before evaporator" temperature too low. Preventing cold loop from freezing. See T_COLDREF_MIN option. |
#Tbc>Max | "Before condenser" temperatire is too high. Overheat protection. See T_BEFORE_CONDENSER_MAX option. |
#Tci<ColdMin | "Cold in" temperature is too low. Preventing cold loop from freezing. See T_COLD_MIN option. |
#Tco<ColdMin | "Cold out" temperature is too low. Preventing cold loop from freezing. See T_COLD_MIN option. |
CWP_ON_CoMin | Cold side pump started beause cold side temperature is too low, so preventing cold loop freeze, see T_COLD_MIN option. |
Additional messages
Message | description |
---|---|
OK:Pr.Cold | Cold side pressure restored. |
OK:Pr.Hot | Hot side pressure restored. |
OK:E.T.Sens. | Temperature sensors restored. |
HWP_ON | Hot side pump powered on. |
Err:errorcode | Error code: 1 = temperature sensor error, 2 = Hot side pressure too high 3 = cold side pressure too low. |
Appendix C: secret appendix
Are you still reading? If yes, your are interested in and this appendix is for you.
About sensors: do not use cheap "waterproof epoxy-covered" sensors. "Waterproof" lasts for a short time.
Buy DS18B20s chips. Cheap or not cheap doesn't matter - I've never seen "bad" DSes. Solder sensors to the wires and cover the sensors with a two layers of 2-component epoxy resin as pictured below. This will work for a years.
For sensors at compressor and discharge (+100°C and higher) use heat resistant sleeves at every wire.
To get precise temperature readings sensors must be insulated from ambient air temperature influence with additional thermal insulation. Temperature readings from most of sensors are interesting, but +/- few degree does not matter. So most of sensors can be covered with insulation as you wish.
But 2 sensors "Before evaporator" and "After evaporator" are critical to EEV and needs an extra attention. Temperature of this sensors must be as close to the temperature of copper tube as it possible. So install Tae and Tbe sensors as pictured below. You can use thermal paste, but there is no significant difference with much more available silicone. Tape isn't shown below, for clarity, but must be used with every insulation layer.
Overall, your system scheme with sensors positions will look like at drawing below. Refrigerators (heat pumps) are very simple inside. The only part is not shown below is an oil filter.
About water(glycol)<->refrigerant heat exchangers. You can use plate heat exchangers. Pros: best efficiency. Cons: costs money.
And oxygen brazing with (20%+)silver+copper solder required here:
You can build your own "tube-in-tube" heat exchangers. It's not hard. Cheaper. The heat exchange efficiency is worse. Very easy soldering.
And also you can think "I'll take old AC parts... Housing... Slightly change... A hour or two, day of work maximum, and i'll got a refrigerant<->water heat exchanger in for a penny!" This idea is obvious. That was a first thing I've tried and do not want to try it anymore. You can also go this way, but to achieve "not very bad" performance it'll take much more than a day and much more than few , even if you have unlimited access to older ACs.
OK, i think that's enough for this appendix, this is a controller page, and not how-to-build-refrigeration-systems page.
Appendix D: Firmware options and fine tunings
QA tests, uncomment to enable
//#define SELFTEST_RELAYS_LEDS_SPEAKER //speaker and relays QA test, uncomment to enable
//#define SELFTEST_EEV //EEV QA test, uncomment to enable
//#define SELFTEST_T_SENSORS //temperature sensors QA test, uncomment to enable
Communication protocol with external world, choose one
//#define RS485_JSON 1 //json, external systems integration
//#define RS485_HUMAN 2 //RS485 is used in the same way as the local console, warning: Use only if 2 devices (server and this controller) are connected to the same RS485 line
#define RS485_MODBUS 3 //default, Modbus via RS485, connection to the display (both sensor or 1602, see https://gitlab.com/valden/) or connection to any other MODBUS application or device
System type, comment both if HP with EEV
//#define EEV_ONLY //Valden controller as EEV controller: NO target T sensor. No relays. Oly EEV. Sensors required: Tae, Tbe, current sensor. Additional T sensors can be used but not required.
//#define NO_EEV //capillary tube or TXV, EEV not used
Which sensor is used to check setpoint, uncomment one of options
#define SETPOINT_THI //"warm floor" scheme: "hot in" (Thi) temperature used as setpoint
//#define SETPOINT_TS1 //"swimming pool" or "water tank heater" scheme: "sensor 1" (Ts1) is used as setpoint and located somewhere in water tank
Some more options
#define HUMAN_AUTOINFO 30000 //print stats to console, every milliseconds
#define WATCHDOG //disable for older bootloaders
Next sections: advanced options Temperature sensors used in a system, comment to disable
#define T_cold_in; //cold side (heat source) inlet sensor
#define T_cold_out; //cold side outlet sensor
#define T_before_evaporator; //"before" and "after evaporator" sensors are required to control EEV, both "EEV_ONLY" and "full" schemes
#define T_after_evaporator; //"before" and "after evaporator" sensors are required to control EEV, both "EEV_ONLY" and "full" schemes
#ifdef SETPOINT_TS1
#define T_sensor_1; //T values from the additional sensor S1 are used as a "setpoint" in "pool" or "water tank heater" schemes
#endif
//#define T_sensor_2; //additional sensor, any source, for example: outdoor temperature, in-case temperature, and so on
#define T_crc; //if defined: enables crankcase T sensor and crankcase heater on relay 4
//#define T_regenerator; //an additional sensor, the regenerator temperature sensor (inlet or outlet or housing) is used only to obtain a temperature data if necessary
#define T_afrer_condenser; //after condenser (and before valve)
#define T_before_condenser; //before condenser (discharge)
#define T_hot_out; //hot side outlet
//in full scheme Hot IN required! optional in "EEV_ONLY" scheme (see "EEV_ONLY" option),
#define T_hot_in; //hot side inlet
Temperature limits
#define MAGIC 0x66; //change this value if you want to rewrite the T setpoint in EEPROM
#define T_SETPOINT 26.0; //This is a predefind target temperature value (start temperature). EEPROM-saved. The value can be changed using 1. Console 2. Changing the "setpoint" on a display 3. Changing this value AND changing "magic number"
#define T_SETPOINT_MAX 48.0; //maximum "setpoint" temperature that an ordinary user can set
#define T_SETPOINT_MIN 10.0; //min. "setpoint" temperature that an ordinary user can set, lower values are not recommended until antifreeze fluids at hot side are used.
#define T_CRANKCASE_MIN 8.0; //compressor (crankcase) min. temperature, HP will not start if T lower
#define T_CRANKCASE_MAX 110.0; //compressor (crankcase) max. temperature, overheating protection, HP will stop if T higher
#define T_CRANKCASE_HEAT_THRESHOLD 16.0;//crankcase heater threshold: heater will be powered on if T lower
#define T_WORKINGOK_CRANKCASE_MIN 25.0;//compressor temperature: additional check. HP will stop if T is lower than this value after 5 minutes of work. Do not set the value too large to ensure normal operation after long pauses.
#define T_BEFORE_CONDENSER_MAX 108.0; //discharge MAX, system stops if discharge higher
#define T_COLDREF_MIN -14.0; //suction min., HP stops if T lower, cold side (glycol) loop freeze protection and compressor protection against liquid
#define T_BEFORE_EVAP_WORK_MIN -25.5; //!!!before evaporator (after valve) min. T; can be very low for a few minutes after startup, ex: capillary tube in some conditions; and for all systems: after long shut-off, lack of reagent, 1st starts, and many others
#define T_COLD_MIN -15.5; //cold side (glycol) loop freeze protection: HP stops if inlet or outlet temperature lower
#define T_HOT_MAX 50.0; //hot loop: HP stops if hot side inlet or outlet temperature higher than this threshold
Watts, cycles times (milliseconds)
#define MAX_WATTS 1000.0 + 70.0 + 80.0 //power limit, watt, HP stops in case of exceeding, example: compressor: ~1000 + hot CP 70 + cold CP 80
#define POWERON_PAUSE 300000 //after power on: wait 5 minutes before the start of HP (protected from power faults)
#define MINCYCLE_POWEROFF 600000 //after a normal compressor stop: 10 minutes pause (max 99999 seconds)
#define MINCYCLE_POWERON 3600000 //after compressor start: minimum compressor operation time, i.e. work time is not less than this value (or more, depending on the setpoint temperature) 60 minutes = 3.6 KK 120mins = 5.4 kK.
#define POWERON_HIGHTIME 7000 //after compressor start: defines time when power consumption can be 3 times greater than normal, 7 sec. by default
#define COLDCIRCLE_PREPARE 90000 //before compressor start: power on cold CP and wait 90 sec; if false start: CP will off twise this time; and (hotcircle_stop_after - this_value) must be > hotcircle_check_prepare or HP will go sleep cycle instead of start
#define DEFFERED_STOP_HOTCIRCLE 1200000 //after compressor stop: wait 20 minutes, if no need to start compressor: stop hot WP; value must be > 0
#define HOTCIRCLE_START_EVERY 2400000 //while pauses: pump on "hot side" starts every 40 minutes (by default) (max 9999 seconds) to circulate water and get exact temperature reading , option used if "warm floor" installation (Thi as setpoint)...
#define HOTCIRCLE_CHECK_PREPARE 300000 //while pauses: ...and wait temperature stabilisation 5 minutes (by default), after that do setpoint checks...
#define HOTCIRCLE_STOP_AFTER (HOTCIRCLE_CHECK_PREPARE + COLDCIRCLE_PREPARE + 30000) //...and then stop after few minutes of circulating, if temperature is high and no need to start compressor; value must be check_prepare + coldcircle_prepare + 30 seconds (or more)
EEV options If you are using capillary tube or TXV: simply skip next section Depending on how many milliseconds are allocated per step, the speed of automatic tuning will change. Remember that you'll see refrigeration system reaction on every step not immediately, but after few minutes, sometimes after tens of minutes.
#define EEV_MAXPULSES 250 //max steps, 250 is tested for sanhua 1.3
//steps tuning: mulliseconds per fast and slow (precise) steps
#define EEV_PULSE_FCLOSE_MILLIS 20 //(20 tube evaporator) fast closing, closing on danger (milliseconds per step)
#define EEV_PULSE_CLOSE_MILLIS 60000 //(50000 tube evaporator) accurate closing while the compressor works (milliseconds per step)
#define EEV_PULSE_WOPEN_MILLIS 20 //(20 tube evaporator) standby (waiting) pos. set (milliseconds per step)
#define EEV_PULSE_FOPEN_MILLIS 1400 //(1300 tube evaporator) fast opening, fast search (milliseconds per step)
#define EEV_PULSE_OPEN_MILLIS 70000 //(60000 tube evaporator) accurate opening while the compressor works (milliseconds per step)
#define EEV_STOP_HOLD 500 //0.1..1sec for Sanhua hold time (milliseconds per step)
#define EEV_CLOSEEVERY 86400000 //86400000: EEV will be closed (zero calibration) every 24 hours, executed while HP is NOT working (milliseconds per cycle)
//positions
#define EEV_CLOSE_ADD_PULSES 8 //read below, additional steps after zero position while full closing
#define EEV_OPEN_AFTER_CLOSE 45 //0 - set the zero position, then add EEV_CLOSE_ADD_PULSES (zero insurance, read EEV guides for this value) and stop, EEV will be in zero position.
//N - set the zero position, than add EEV_CLOSE_ADD_PULSES, than open EEV on EEV_OPEN_AFTER_CLOSE pulses
//i.e. it's a "waiting position" while HP not working, value must be <= MINWORKPOS
#define EEV_MINWORKPOS 50 //position will be not less during normal work, open EEV to this position after compressor start
//temperatures
#define EEV_PRECISE_START 7.0 //(8.6 tube evaporator) precise tuning threshold: make slower pulses if (real_diff-target_diff) less than this value. Used for fine auto-tuning
#define EEV_EMERG_DIFF 1.7 //(2.5 tube evaporator) liquid at suction threshold: if dangerous condition occured: real_diff =< (target_diff - EEV_EMERG_DIFF) then EEV will be closed to min. work position //Ex: EEV_EMERG_DIFF = 2.0, target diff 5.0, if real_diff =< (5.0 - 2.0) then EEV will be closed to EEV_MINWORKPOS
#define EEV_HYSTERESIS 0.5 //(0.6 tube evaporator) hysteresis, to stop fine tuning: must be less than EEV_PRECISE_START, ex: target difference = 4.0, hysteresis = 0.3, no EEV pulses will be done while real difference in range 4.0..4.3
#define EEV_TARGET_TEMP_DIFF 3.6 //(3.6 tube evaporator) target difference between Before Evaporator and After Evaporator, the head of whole algorithm
//additional options
#define EEV_REOPENLAST 1 //1 = reopen to last position on compressor start, useful for ordinary schemes with everyday working cycles, 0 = not
#define EEV_REOPENMINTIME 40000 //after system start: min. delay between "min. work pos." (must be > 0 in this case and > waiting position) set and reopening start
//#define EEV_MANUAL //comment to disable, manual set of EEV position via console; warning: this option will stop all EEV auto-activities, including zero position find procedure; so this option not recommended: switching auto/manual mode from console after startup is a better way
//do not use next option untill you're not really need it
//#define EEV_DEBUG //debug, usefull during system fine tuning, works both with local serial and RS485_HUMAN
Communication addresses
const char devID = 0x45; //used only if JSON communication, does not matter for modbus and Valden display https://github.com/OpenHP/
const char hostID = 0x30; //used only if JSON communication, not used for modbus
Last option
#define MAX_SEQUENTIAL_ERRORS 15 //max cycles to wait auto-clean error, ex: T sensor appears, stop compressor after counter exceeded (millis_cycle * MAX_SEQUENTIAL_ERRORS)
Appendix D: bill of materials
Part | Quantity |
---|---|
1206 Resistors: | |
10 | 1 |
100 | 1 |
120 | 1 |
1K | 7 |
10K | 6 |
100K | 2 |
22 | 1 |
2.2K | 4 |
470 | 10 |
1206 Caps: | |
0.01uF | 2 |
0.1uF | 4 |
1uF | 8 |
10uF | 5 |
1206 LEDs: | |
Red (error LEDs) | 2 |
Green (OK LED) | 1 |
Yellow | 11 |
SOP(SOIC) ICs: | |
ADM2587EBRWZ (SOIC-20) | 1 |
74HC4067D (SOIC-24) | 1 |
74HC595D (SOP-16) | 3 |
ULN2003A_(SOP-16) | 2 |
817S (SOP-4) | 2 |
XH2.54 Headers + Plugs: | |
XH2.54-6P header + 6P plug | 4 |
XH2.54-3P header + 3P plugs | 2 |
XH2.54-2P header + 2P Plugs | 1 |
XH2.54 Crimp terminal | 40 |
Power terminals: | |
6.35 Blade terminal (726386-2 or same) | 16 |
6.35 Quick disconnect crimp terminal insulated | 16 |
Others: | |
10nF HV-9.0x3.0 (blue disc 2kV HV cap) | 1 |
22uf_16v D5.0xF2.0 (electrolytic cap) | 1 |
Resistor Network*4 DIP-1X5P-2.54 (3..5K) | 3 |
MMBT2222A (SOT-23-3) | 1 |
LM7805 (TO-220) | 1 |
SMIH-12VDC-SL-C | 4 |
BUZZER-R9.0-2P-4.0 | 1 |
ARDUINO PRO MINI | 1 |
Power supply, 12v1.25A 70x30x40 (or any 0.5A+) | 1 |
DS18B20 | 12 |
usb→uart (to upload firmware) | 1 |
Current sensor sct-013-000 | 1 |
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