Heliox UV MP

The Heliox UV MP treatment system has a number of advantages over chemical disinfection systems, since virtually UV light does not alter the physical and chemical composition of water, it is very effective against any type of organism (algae, bacteria, virus, fungi, yeasts, etc.) further minimizing the risks of handling and dosing of hazardous chemicals. Moreover, UV treatment reduces the levels of combined chlorine in the water, thereby producing significant water and energy savings by reducing the volume and frequency of pool waterrenewals.

The Heliox UV MP treatment systems have been designed and manufactured with the latest technology in UV treatment of water, thus ensuring continuous operation and minimal maintenance.
The proposed control architecture for HELIOX UV MP system has a number of features that allow the highest levels of reliability, efficiency and scalability.

Because the systems incorporate calibrated radiation and flow sensors, continuous adjustment of the lamp power is allowed, thus optimizing energy consumption and lifetime. Calibrated sensors do not require any user action on them.

HELIOX UV MP systems manage two parameters when setting the lamp power, radiation measured by the sensor and flow. Thus, the system sets a nominal radiation for each model, which is determined by the maximum treatment flow to ensure a dose of 60 mJ/cm2. If the flow to be treated is less than the nominal one, so too will be the radiation needed, so the system will decrease the output power, optimizing the energy consumption and increasing lamp life. Like the current UV systems, whether radiation decreases due to loss of efficiency of the lamp, turbidity, etc., the system will adjust the lamp power to ensure the nominal dose.

The lamp power system is based on an electronic ballast which allows continuous operation with high efficiency (greater than 95%).

Specification

The control architecture used in Heliox UV PM systems has a number of features that make them reliable, energy-efficient and scalable to the highest possible level.
The Heliox UV MP systems use two parameters for adjusting the power setting: average radiation and flow. All models have a rated radiation profile that ensures a dose of 60mJ/cm2. If the flow is lower than the rated value, the same will apply to the required radiation level and the system reduces the power input, thus optimising power consumption and the lamp’s lifetime. Likewise, if radiation drops due to losses caused by cloudy water, scaling or lamp emission efficiency, the system will adjust the power so that the right dose is supplied.
- More compact design (UV reactor in AISI-316).
- Adjustable to between 70 and 100% of rated power, in 1% increments, by means of a self-cooling electronic
  ballast.
- Fluidra technology (design and manufacturing).
- Calibrated UV-C radiation sensor (mW/cm2). Precise dose control. Instant power adjustment to process
  conditions. Saves energy and extends the lamp’s lifetime.
- Advanced colour touch screen. System menu for browsing process parameters and log files.
- All UV MP 50-->450 and UV MP 50AWP -> 450AWP models are built in compliance with UL NSF.

Technical specification

Unique ref.Heliox_UV_MP
Product familyCommercial Pool Equipment
Product groupUV Automatic Disinfection
TypeObject (single object)
Date of publishing2018-03-12
Edition number1

Links

Material mainStainless steel
Designed inSpain
Manufactured inSpain

Classification

BIMobject CategorySports & Recreation - Swimming pool
IFC classificationController

Region availability

Europe	Asia	North America	Africa	South America	Oceania
Åland Islands	Afghanistan	Anguilla	Algeria	Argentina	American Samoa
Albania	Armenia	Antigua and Barbuda	Angola	Bolivia	Australia
Andorra	Azerbaijan	Aruba	Benin	Brazil	Cook Islands
Austria	Bahrain	Barbados	Botswana	Chile	Federated States of Micronesia
Belarus	Bangladesh	Belize	Burkina Faso	Colombia	Fiji
Belgium	Bhutan	Bermuda	Burundi	Ecuador	French Polynesia
Bosnia and Herzegovina	British Indian Ocean Territory	British Virgin Islands	Cameroon	Falkland Islands (Islas Malvinas)	Guam
Bulgaria	Brunei	Canada	Cape Verde	French Guiana	Kiribati
Croatia	Cambodia	Caribbean Netherlands	Central African Republic	Guyana	Marshall Islands
Cyprus	China	Cayman Islands	Chad	Paraguay	Nauru
Czech Republic	Christmas Island	Collectivity of Saint Martin	Comoros	Peru	New Caledonia
Denmark	Cocos (Keeling) Islands	Costa Rica	Côte d'Ivoire	Suriname	New Zealand
Estonia	Georgia	Cuba	Democratic Republic of the Congo	Uruguay	Niue
Faroe Islands	Hong Kong	Curaçao	Djibouti	Venezuela	Norfolk Island
Finland	India	Dominica	Egypt		Northern Mariana Islands
France	Indonesia	Dominican Republic	Equatorial Guinea		Palau
Germany	Iran	El Salvador	Eritrea		Papua New Guinea
Gibraltar	Iraq	Greenland	Eswatini		Pitcairn Islands
Greece	Israel	Grenada	Ethiopia		Samoa
Guernsey	Japan	Guadeloupe	Gabon		Solomon Islands
Hungary	Jordan	Guatemala	Ghana		Timor-Leste
Iceland	Kazakhstan	Haiti	Guinea		Tokelau
Ireland	Kuwait	Honduras	Guinea-Bissau		Tonga
Isle of Man	Kyrgyzstan	Jamaica	Kenya		Tuvalu
Italy	Laos	Martinique	Lesotho		United States Minor Outlying Islands
Jersey	Lebanon	Mexico	Liberia		Vanuatu
Latvia	Macau	Montserrat	Libya		Wallis and Futuna
Liechtenstein	Malaysia	Nicaragua	Madagascar
Lithuania	Maldives	Panama	Malawi
Luxembourg	Mongolia	Puerto Rico	Mali
Malta	Myanmar (Burma)	Saint Kitts and Nevis	Mauritania
Moldova	Nepal	Saint Lucia	Mauritius
Monaco	North Korea	Saint Pierre and Miquelon	Mayotte
Montenegro	Oman	Saint Vincent and the Grenadines	Morocco
Netherlands	Pakistan	Saint-Barthélemy	Mozambique
North Macedonia	Palestine	Sint Maarten	Namibia
Norway	Philippines	The Bahamas	Niger
Poland	Qatar	Trinidad and Tobago	Nigeria
Portugal	Saudi Arabia	Turks and Caicos Islands	Republic of the Congo
Romania	Singapore	U.S. Virgin Islands	Reunion
Russia	South Korea	United States	Rwanda
San Marino	Sri Lanka		Saint Helena
Serbia	Syria		São Tomé and Príncipe
Slovakia	Taiwan		Senegal
Slovenia	Tajikistan		Seychelles
Spain	Thailand		Sierra Leone
Svalbard and Jan Mayen	Türkiye		Somalia
Sweden	Turkmenistan		South Africa
Switzerland	United Arab Emirates		South Sudan
Ukraine	Uzbekistan		Sudan
United Kingdom	Vietnam		Tanzania
Vatican City	Yemen		The Gambia
			Togo
			Tunisia
			Uganda
			Western Sahara
			Zambia
			Zimbabwe