OZOTECH AIM P30 & P50 Ozone Generators

Introduction

Welcome to the AIM P30 and AIM P50 ozone generator user manual. Congratulations on your purchase of an AIM P Series generator! This comprehensive user manual is designed to be your ultimate guide to unlocking the full potential of your new AIM P Series generator. Whether you're a first-time user or an experienced water treatment professional, this manual will provide you with the knowledge and insights you need to make the most out of your AIM P Series generator.

What's Inside

In this manual, you'll find clear and concise instructions on how to set up, operate, and maintain your AIM P Series generator. The content is organized in a logical sequence, from initial unboxing to advanced usage techniques, making it easy to navigate and find exactly what you need. Each section is accompanied by helpful tips and troubleshooting suggestions, all aimed at enhancing your experience. Note: Diagrams and figures from the original document are described textually within the relevant sections.

Your Feedback Matters

Ozotech, Inc. is dedicated to continuous improvement, and your feedback is invaluable. If you have suggestions for improving this manual, please contact Ozotech. If you encounter any challenges, please reach out to your local dealer.

Thank you for choosing Ozotech.

1.0 Caution

Read the following safety guidelines thoroughly before attempting to operate or install your equipment.

• ⚠️ As with all electrical devices, this equipment should never be allowed to come in contact with water.
• ⚡ Only qualified personnel should be allowed to set up, maintain and operate this equipment.
• ⚡ The equipment must be operated using a properly grounded electrical circuit that is protected by either a fuse or circuit breaker.
• ⚡ Do not use an extension cord to supply power to this equipment.
• ⚡ Use a power conditioner if line voltage fluctuates outside of specified range.
• ⚡ Units must never run with internal air flow rate or pressure below manufacturer's specifications.
• ⚡ Unit must be disconnected from power prior to performing service or repair.

* Ozotech, Inc., assumes no liability for damages or injuries incurred by misuse of this product.

2.0 Theory of Operation

Your AIM P Series ozone generator is a state-of-the-art device designed to produce a significant amount of highly concentrated ozone by means of Ozotech's proprietary Advanced Impedance Management technology, "AIM". The technology utilized by Ozotech, Inc., to generate ozone is known as "Plasma Discharge".

By supplying a high purity oxygen feed gas through the ozone generator, along with the proper amount of back pressure applied, concentrations above 7.5% by weight (or an output of around 50 grams per hour) can be achieved. Your AIM P Series generator will come pre-set to operate in "Manual Ozone Adjustment" mode. This means that after installing your AIM P Series ozone generator, simply turn the "Ozone Enable" switch to "Ozone ON".

The "Manual Ozone Adjustment" knob can be adjusted to dial the % of power the generator will run at, which is displayed on the "Power Display". If you are planning on running the system with a 4-20mA, 0-10VDC, or a 0-5VDC (0-10mA maximum) external signal, you will need to remove power at the source of the unit and run the appropriate signal cables to the "External Signal Port" terminal block.

Replace the lid and reestablish power. Move the "Ozone Enable" switch to "ON". If using a remote signal, turn the "Signal Input" switch to "Remote Signal". You can now use your controller to operate your generator.

2.1 Plasma Discharge Ozone Generation

Plasma discharge generators create ozone through the action of high voltage, low current electrical "arcs" across an air space. When oxygen (O2) is passed through the air space, some molecules are split, resulting in "free" oxygen atoms which quickly attach themselves to intact O2 molecules.

The result is a very unstable form of oxygen, O3 (ozone). It is the extra atom of oxygen that gives ozone its superior oxidation capabilities. Unlike other oxidants, such as chlorine and hydrogen peroxide, ozone reverts back into oxygen over time, making it an environmentally friendly oxidizer.

3.0 Operating Conditions

Your AIM P Series ozone generator requires special operating conditions to maintain performance and reliability. Warranty coverage of your equipment is contingent upon strict compliance with the operating conditions specified in this manual.

3.1 Operating Environment

EXTERNAL

Choose a location for your equipment that is clean, dry, and free of excessive airborne particles. Your equipment requires a constant flow of clean air for proper internal cooling. A minimum of six (6) inches clearance is required around the front, bottom, left, and right sides of the unit to eliminate restriction of air flow. Direct exposure to moisture must be avoided. The AIM P Series ozone generator chassis is designed to be drip-proof; it is not watertight.

Mount your AIM P Series ozone generator in the best possible operating environment available at your installation site.

INTERNAL

The operating environment inside the chassis is also important. Maintaining a clean, dry unit will increase overall performance and extend service life. A common cause of failure is un-contained corona (electrical arcs) within the chassis environment. Moisture and dust facilitate this condition, helping to create a "path" for the plasma to develop and follow. Once established, the plasma usually does not stop until it has become severe enough to cause catastrophic failure of the plasma discharge, and subsequently blows the fuse. Note: If this condition develops, contact the manufacturer.

3.2 Internal Air Flow Specifications

As mentioned in the Theory of Operation section, plasma discharge relies upon a flow of high purity oxygen passing through the ozone generator.

The rate at which air is drawn (or forced) through the ozone generator is user adjustable. You may fine-tune the flow rate to best suit your specific application. However, in no case should the air flow rate be allowed to drop below the minimum values specified below. Failure to provide minimum air flow rates may allow your ozone generator to develop too much heat, possibly leading to equipment failure.

3.3 Preparation of Input Air

Regardless of the method of ozone generation, properly preparing the input air (feed gas) will pay huge dividends in performance and reliability. Ozotech, Inc. does not recommend the use of any AIM Series ozone generator without air preparation. Warranty coverage of your ozone generator is contingent upon operation with air preparation equipment.

The key to air preparation is the removal of Hydrogen (H) and Nitrogen (N) found in ambient air. When atoms of Hydrogen and Nitrogen are subject to plasma discharge, by-products such as Nitrous acid (HNO2) and Nitric acid (HNO3) are formed. The formation of these compounds inhibits performance and increases the frequency of maintenance.

To understand how performance is affected, recall from the Theory of Operation section that ozone is created by splitting an oxygen molecule (O2) and then joining the liberated oxygen atoms (O) with intact oxygen molecules. Imagine that in addition to oxygen molecules, your feed gas also contains Hydrogen and Nitrogen atoms. After being subjected to plasma, some of the Hydrogen and Nitrogen atoms will attach themselves to intact oxygen molecules, forming HNO3 (Nitric acid). Others will attach themselves to ozone molecules, forming HNO2 (Nitrous acid). The formation of these compounds reduces performance potential. If ozone molecules were not being "used" by Hydrogen and Nitrogen in the formation of acids, more would be available for oxidation. Likewise, if oxygen molecules were not "used" to form acids, they would be available for the creation of more ozone.

Increased service life and reduction in maintenance are gained due to the same principle. With less HNO2 and HNO3 being formed, plasma discharge maintenance can be reduced without the risk of acid buildup. Since both HNO2 and HNO3 are highly conductive, they are capable of producing a path for corona (electrical arcs) inside the Plasma block. As stated previously, once an arc has started, catastrophic failure is the usual result.

Your AIM P Series ozone generator must be used with a positive pressure air preparation device. Negative pressure devices, such as heat-regenerated desiccant air dryers, rely upon the action of the venturi injector to draw air through the generator (and the dryer). This method is not utilized with the AIM P Series generator due to it introducing moisture-laden ambient air. Positive pressure devices, such as the ProO2 or AirSep series oxygen concentrators, utilize an internal air compressor to push prepared air through the generator.

Your AIM P Series generator is designed for not more than 50 psi of internal pressure.

3.4 Input Power Requirements

The AIM P30, powered by 115 or 230VAC at 50/60Hz, accommodates a wide range of world supply voltages and frequencies. The AIM P50 is powered by 115VAC 50/60Hz or 230VAC 50/60Hz. It is extremely important that your equipment is provided with the appropriate operating power source. Most supply voltages fluctuate, so it is necessary to monitor your voltage and assure it is within acceptable variance values listed below.

• Voltage = (Specified) +/- 5%
• Frequency = (Specified) +/- 5%

Power Consumption

• AIM P30: Stand-By Mode = 16 Watts; Ozone Enabled Mode (@100% power) = 207 Watts
• AIM P50: Stand-By Mode = 16 Watts; Ozone Enabled Mode (@100% power) = 300 Watts

Wiring Instructions

• For 115 VAC: Connect the Line wire (Black) to "L1", the Neutral wire (White) to "N", and the Ground wire (Green, Green/Yellow, or bare) to ⚡ on the input terminal block.
• For 230 VAC: Connect the Line 1 wire (Brown) to "L1", the Line 2 wire (Blue) to L2 wire, and the Ground wire (Green, Green/Yellow, or bare) to ⚡ on the input terminal block.

Note: If your line voltage fluctuates beyond acceptable variance, it will be necessary to connect your equipment to a line conditioner.

4.0 Maintenance

AIM P Series generators are designed and delivered for maximum efficiency and long life. No adjustments, other than fine-tuning the air flow rate to match user-specific requirements, should be made by the end user. Simple maintenance and appropriate operating conditions are the only requirements to keep the unit functioning within manufacturer's specifications. There must be at least 5psi of back pressure applied when operating the AIM P Series generators. This is accomplished by using the labeled "back pressure adjustment" control knob located on the front of the generator.

Performing any other modifications or adjustments to internal components will cause the unit to function outside of the manufacturer's specifications and will cause damage to the unit not covered under terms of warranty. Maintenance should only be performed by qualified individuals. Your ozone generator operates under conditions of high voltage; maintenance personnel should be trained in electrical safety.

4.1 Plasma Block Maintenance

AIM P Series plasma generators are completely intrinsic modular units, with no user maintenance involved. If at some point a noticeable decrease in ozone production presents itself over time, moisture has most likely accumulated inside the plasma block causing a build up of nitric acid. If this should occur, perform the below procedure.

Plasma Block Nitric Acid Removal Process

(See Figure 1 description for component locations)

1. Disconnect all power from the AIM P Series generator at its source.
2. Disconnect the "Air Inlet" and "Ozone Outlet" lines from the Plasma Block itself.
3. Connect customer supplied tubing lines (3/8" ID PVC tubing) to the Plasma Block inlet and outlet ports.
4. Run isopropyl alcohol from the air inlet line until it starts to exit the ozone outlet line.
5. Work the alcohol back and forth through the Plasma Block.
6. Discharge the alcohol through the ozone outlet port until the alcohol exits clear, and free of any yellow/brown tinge indicating nitric acid.
7. Reconnect the generator's original "Air Inlet" and "Ozone Outlet" lines.
8. Operate the oxygen concentrator or bottled oxygen through the generator for approximately 10 minutes to ensure the alcohol is cleared out of the Plasma Block prior to reapplying power to the unit.

Figure 1 Description: Air Inlet & Ozone Outlet Ports

This figure shows the front panel of the generator. It labels the "Ozone Outlet Port" and the "Air Inlet Port" which are connections for tubing. It also indicates maximum oxygen pressure and notes to use copper conductors only for indoor use.

4.2 Intake Filter Maintenance

The intake filter is located on the side of the chassis, as shown in Figure 2. This filter removes dust particles from the air drawn into the chassis. Proper cooling of internal components requires filters to be clean, dry, and intact.

Procedure:

1. Remove the top inside screws of the louver.
2. Loosen, but do not remove, the bottom two screws of the louver.
3. Remove the intake filter from behind the louver.
4. Clean or replace the intake filter as needed.
5. Install the intake filter in reverse order.

Frequency of Maintenance

• Every 2,190 hours = 3 months (approx. 730.485 hrs./month)

To Clean Intake Filter:

• Remove filter media. Wash gently in soap and water. Dry thoroughly. Inspect for tears, holes, etc. If the filter is intact, replace by reversing the previous step.

Note: Depending on the severity of your specific environment, it may be necessary to increase the frequency of maintenance.

Frequency of Replacement

• Every 4,383 hours (6 months)

To Replace Intake Filter:

The replacement procedure is identical to the maintenance procedure.

Note: Depending on the severity of your specific environment, it may be necessary to increase the frequency of maintenance.

Figure 2 Description: Intake Filter Location

This figure shows the rear or side panel of the generator. It displays the "OZONE OUTLET" and "AIR INLET" ports, and a "POWER INPUT" dial. A louvered vent is visible, and an annotation indicates that the "Intake air filter is located behind louver".

4.3 Chassis Maintenance

Proper maintenance of your generator chassis will provide more than aesthetic advantages. Dust and moisture can contribute to a path for electrical arcs. A clean internal environment will reduce the likelihood of corona outside the plasma block.

Frequency of Maintenance

• Every 2,190 hours (3 months)

To Maintain Chassis:

• Disconnect the unit from the power source.
• Remove the chassis lid.
• Using a clean, dry cloth, carefully wipe out the inside of the chassis and all internal components to remove any dirt or debris. Use a low pressure (≤20 psi) stream of compressed air or a can of compressed air to blow dust from electrical components.
• Using a damp cloth, clean the outside of the unit. A mild detergent may be used.
• Thoroughly dry the chassis, inside and out.

4.4 Check Valve & Vacuum Prevention Device Replacements

It is strongly suggested that check valves and vacuum prevention devices are closely inspected as often as possible, such as each time maintenance of any type is performed. If water is visible between the check valve and the ozone generator, cracks are visible in the check valve body, or foreign matter has built up on the internal O-ring, replacement should be performed immediately, regardless of elapsed time since last replacement.

The minimum required replacement schedule is listed below and must be performed on schedule, even if the check valve appears sound, to maintain warranty terms.

Frequency of Replacement (Check Valve)

• Every 6 months

To Replace Check Valve (See Figure 3)

• Disconnect the unit from the power source.
• Allow the ozone generator to clear of ozone gas.
• Remove tubing from the check valve barb fitting on both sides.
• Trim approximately one inch from the end of each tube to remove distortion caused by the barbed adapter.
• Place the new check valve assembly in-line, between the ozone generator and the venturi injector. The check valve flow direction must point toward the venturi.

Frequency of Replacement (Vacuum Prevention Device)

• Every 12 months

To Replace Vacuum Prevention Device (See Figure 4)

• Disconnect the unit from the power source.
• Allow the ozone generator to clear of ozone gas.
• Unscrew the vacuum prevention device.
• Install the new vacuum prevention device.

Figure 3 Description: Check Valve Replacement

This figure shows two images related to check valve replacement. The top image illustrates disconnecting tubing from barb fittings and trimming the tubing ends. The bottom image shows a check valve (Part # 47018-304) with arrows indicating the correct flow direction, which must point toward the venturi injector.

Figure 4 Description: Vacuum Prevention Device

This figure shows a vacuum prevention device connected in-line with tubing.

5.0 Fusing

There are fuses connected to live source conductors that are accessible from the outside of the chassis. Figure 5 shows the fuse locations. Fuse size and value are listed below:

Figure 5 Description: Chassis Component Details (Front)

This figure shows the front panel of the generator chassis. It labels various controls and indicators including: "POWER DISPLAY", "FAULT LIGHT", "OZONE ENABLE" switch, "OZONE ENABLE" indicator, "SIGNAL INPUT" selector, "SIGNAL" display, "MANUAL ADJUST" knob, "DATA PORT", "BACK-PRESSURE GAUGE", "BACK-PRESSURE ADJUST" knob, "AIR FLOW METER", and "Fuses".

Figure 6 Description: Chassis Component Details (Right Side)

This figure shows the right side of the generator chassis. It labels the "OZONE OUTLET" and "AIR INLET" ports, and the "POWER INPUT" dial which indicates "115/230VAC - 50/60 Hz".

4.1 Plasma Block Maintenance (Internal Components)

Figure 7 Description: AIM P30 Internal Components

This figure shows an internal view of the AIM P30 ozone generator. Key components labeled include: "Power Supply", "Power Terminal Block", "Cooling Fan", "Plasma Block", "Vacuum Prevention Device", "Pressure Switch", "Data Port", "Control Switches", "Safety Switch", "Air Inlet", "Ozone Outlet", and "Air Flow Meter".

Figure 8 Description: AIM P50 Internal Components

This figure shows an internal view of the AIM P50 ozone generator. Similar to the AIM P30, it labels components such as "Power Supply", "Power Terminal Block", "Cooling Fan", "Plasma Block", "Vacuum Prevention Device", "Pressure Switch", "Data Port", "Control Switches", "Safety Switch", "Air Inlet", "Ozone Outlet", and "Air Flow Meter". It also shows the main circuit board and other electronic components.

6.0 Spare/Replacement Parts

(*) Denotes recommended spare maintenance parts with initial purchase. Followed by quantity, per unit, recommended for one year's scheduled maintenance.

Note: Spare parts are listed for only the most commonly purchased models. For options not included in this section, consult your dealer.

7.0 Troubleshooting Guide

A qualified electrician should perform troubleshooting, in accordance with sound electrical safety practices.

8.0 Limited Warranty

OZOTECH, Inc., warrants the AIM P30 and AIM P50 ozone generators to be free from defects in parts and workmanship for twelve (12) months from date of invoice, under conditions of normal use. The plasma cell is warrantied against catastrophic electrical failure for 3 years from date of invoice. All other parts, repaired or replaced, will be warranted only for the remainder of the original warranty period.

OZOTECH, Incorporated will refund the purchase price, perform repairs, or replace equipment, at the option of OZOTECH, Incorporated.

The warranty shall be null, void, and non-binding upon OZOTECH, Incorporated if OZOTECH, Incorporated (or authorized service center) determines the cause of malfunction or defect to be a result of:

1. Failure to perform proper maintenance as defined and recommended in this manual.
2. Failure to adhere to and provide proper operating conditions, as defined in this manual, including operation outside of temperature range, operating in wet or dirty environment, or operation outside of manufacturer's specifications.
3. Adjustments made by user other than product output flow rate within ranges specified by manufacturer.

OZOTECH, Incorporated assumes no liability for damages incurred by deliberate or incidental misuse of this product, or damages incurred in transit.

Read Limited Product Warranty Link

9.0 Service Returns

If the need arises to return your equipment for service, the following procedure must be followed to ensure accurate and timely processing of repairs.

• Obtain model number/name of unit to be returned.
• Contact Ozotech, Inc. and request a Return Material Authorization (RMA) form. Make sure to give the factory representative an accurate and current shipping address.
• Provide a description detailing the problem with the unit. Be as specific as possible.
• After receipt of RMA form, package unit for shipment. Enclose the RMA form with the unit. Use the original packaging materials if possible. If not, please package the product to ensure against shipping damage.
• Clearly write the RMA number on the outside of the shipping package.
• Verify that the address is correct and current.
• Shipments that are not factory authorized will be refused.

It is recommended that you ship with a reputable and reliable shipping company, and that the contents of the package are insured. Ozotech, Inc. accepts no responsibility for damage or loss of equipment in transit.

ALL FREIGHT CHARGES INTO THE FACTORY MUST BE PREPAID.

If the repair is covered under warranty, the factory will pay return shipping charges (surface rates only) to the address listed on the RMA, within the Continental United States.

If the repair is not covered under warranty, the returning party is responsible for payment of return shipping and handling charges, as well as labor and equipment costs associated with the repair.

Performance Graphs

Figure 9 Description: Performance Graph (AIM P30 @ 5 PSI)

This is a bar chart showing performance data for the AIM P30 generator at 5 psi cell pressure. The X-axis represents Air Flow Rate in SCFH (5, 10, 15, 20, 30 SCFH). The Y-axis represents output metrics. The blue bars indicate '%/wt' (percentage by weight) and the orange bars indicate 'G/Hr' (grams per hour). The graph is accompanied by the following conditions: 70°F Ambient Temperature, 84°-86°F Block Temperature, 242 Watts power consumption, 120 VAC/60Hz power, Feed gas: 95% O2 Purity, and operating at 2,500 ft. msl.

Figure 10 Description: Performance Graph (AIM P30 @ 10 PSI)

This is a bar chart showing performance data for the AIM P30 generator at 10 psi cell pressure. The X-axis represents Air Flow Rate in SCFH (5, 10, 15, 20, 30 SCFH). The Y-axis represents output metrics. The blue bars indicate '%/wt' and the orange bars indicate 'G/Hr'. The graph is accompanied by the following conditions: 70°F Ambient Temperature, 84°-86°F Block Temperature, 242 Watts power consumption, 120 VAC/60Hz power, Feed gas: 95% O2 Purity, and operating at 2,500 ft. msl.

Figure 11 Description: Performance Graph (AIM P30 @ 15 PSI)

This is a bar chart showing performance data for the AIM P30 generator at 15 psi cell pressure. The X-axis represents Air Flow Rate in SCFH (5, 10, 15, 20, 30 SCFH). The Y-axis represents output metrics. The blue bars indicate '%/wt' and the orange bars indicate 'G/Hr'. The graph is accompanied by the following conditions: Air Cooled, 70°F Ambient Temperature, 84°-86°F Block Temperature, 242 Watts power consumption, 120 VAC/60Hz power, Feed gas: Compressed O2, and operating at 2,500 ft msl.

Figure 12 Description: Performance Graph (AIM P50 @ 10 PSI)

This is a bar chart showing performance data for the AIM P50 generator at 10 psi cell pressure. The X-axis represents Air Flow Rate in SCFH (8, 11, 12, 14.3, 17.5, 20.7 SCFH). The Y-axis represents output metrics. The blue bars indicate '%/wt' and the orange bars indicate 'G/Hr'. The graph is accompanied by the following conditions: Air Cooled, 70°F Ambient Temperature, 92°-99°F Block Temperature, 400 Watts power consumption, 120 VAC/60Hz power, Feed gas: Compressed O2, and operating at 2500 ft. msl.

Figure 13 Description: Performance Graph (AIM P50 @ 20 PSI)

This is a bar chart showing performance data for the AIM P50 generator at 20 psi cell pressure. The X-axis represents Air Flow Rate in SCFH (5.3, 8.5, 13.25, 20, 26.5, 35 SCFH). The Y-axis represents output metrics. The blue bars indicate '%/wt' and the orange bars indicate 'G/Hr'. The graph is accompanied by the following conditions: Air Cooled, 70°F Ambient Temperature, 92°-99°F Block Temperature, 400 Watts power consumption, 120 VAC/60Hz power, Feed gas: Compressed O2, and operating at 2500 ft. msl.

Wiring Diagrams

Figure 14 Description: AIM P30 115/230 Vac Wiring Diagram

This figure is a wiring diagram for the AIM P30 model, illustrating the electrical connections for both 115 Vac and 230 Vac configurations. It details the layout of components, power inputs (L1, L2, N, Ground), and internal wiring paths.

Figure 15 Description: AIM P50 115 Vac Wiring Diagram

This figure is a wiring diagram for the AIM P50 model, specifically for the 115 Vac configuration. It shows the electrical connections, component layout, and power input details.

Figure 16 Description: AIM P50 230 Vac Wiring Diagram

This figure is a wiring diagram for the AIM P50 model, specifically for the 230 Vac configuration. It illustrates the electrical connections, component layout, and power input details.