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Attempts to regulate the air conditioning (AC) and commercial refrigeration markets for the benefit of the environment are nothing new. During the past 25+ years, various legislative actions have limited the use of various refrigerants that depleted ozone or emitted greenhouse gases, both of which have been shown to contribute to global warming potential (GWP).
The most recent actions, including the EPA’s Significant New Alternatives Policy (SNAP) program and the much more recent American Innovation and Manufacturing Act (AIM), are further driving growth of low-GWP refrigerants. While this is good news for the environment, these low-GWP refrigerants are not without their own challenges. They may increase energy consumption, introduce added safety risks and require significant equipment modifications.
A history of efforts to benefit the environment
Refrigeration systems contribute to the emission of greenhouse gases when a leak occurs of a high-GWP refrigerant. The two refrigerants most commonly used in the early days of refrigeration were ammonia and carbon dioxide (CO2). Both proved to be problematic for different reasons. Ammonia is toxic and carbon dioxide requires extremely high pressures to operate in a refrigeration cycle.
As a result, both refrigerants lost popularity when Freon 12 (dichloro-diflouro-methane) hit the market. Among other benefits, Freon is extremely stable, non-toxic, and operates at moderate pressures. Unfortunately, it was also shown to have a high ozone depletion potential (ODP), which is the primary reason is has since been banned from use globally.
Numerous other refrigerants have also been banned through SNAP, which was established under the Clean Air Act to identify and evaluate substitutes for ozone-depleting substances. The EPA has since published numerous rules about what is and is not acceptable under SNAP, creating tremendous confusion in the industry. The policies established under SNAP took on greater meaning due to the AIM Act, which went into effect in 2020. The AIM Act requires the EPA to implement a phase down of the production and consumption of hydrofluorocarbons (HFC refrigerants) to reach approximately 15% of their 2011-2013 average annual levels by 2036. HFCs are of particular concern since they are classified as potent greenhouse gases that contribute to climate change.
Pros and cons of preferred low-GWP alternatives carbon dioxide (CO2) and propane (R290)
Tighter environmental legislation is opening the door for increased demand for low-GWP refrigerants.
Two of the more popular options on the market today are CO2 and propane (R290). Both have a long history in refrigeration but have recently again emerged as front-runners due to their low environmental impact. CO2 is the more commonly used for many reasons, including:
A key challenge of using CO2, however, is that it operates at a far higher pressure than other natural and synthetic refrigerants. This increases the risk of leaks which, in turn, necessitates the use of more durable, costly components and piping to handle the greater pressure and added controls and other safety features, many of which increase energy consumption due to high ambient temperatures.
As a hydrocarbon, R290 provides several equally attractive benefits, including superior thermodynamic properties and greater heat capacity. These combined characteristics allow R290 to absorb more heat at an accelerated rate, resulting in higher device energy efficiency with faster temperature recovery and lower energy consumption.
More importantly from an environmental standpoint, R290 (like all hydrocarbons) has no ozone depleting properties and a low GWP of 3. It is also compatible with materials commonly used in the construction of refrigeration and air conditioning equipment, is readily available and relatively inexpensive. It can be stored and transported in steel cylinders similar to how other common refrigerants are handled.
A major concern about R290 is that it’s highly flammable. That’s why refrigerant charge limits are in place, as well as other special safety standards when using R290.
Overcoming the challenges of CO2
The higher operating pressure of CO2 creates a few design challenges. But most of these can be overcome, albeit at a higher cost. Key are material upgrades, such as thicker-walled piping or high-strength K65 copper alloys.
Parker manufactures an array of valves, seals and controllers that are specially rated for CO2 high-pressure refrigeration systems. This includes pressure-rated electric expansion valves, ball valves with integrated pressure relief, stepper motor-driven pressure regulating valves, pulse width modulation valves that manage refrigerant flow and pressure-regulating gas cooler/flash gas bypass valves.
Steel piping is also being used in some instances for high pressure CO2 and the addition of electronic controls which can monitor and record pressures, temperatures and additional parameters. This includes pressure-rated electric expansion valves, ball valves with integrated pressure relief, stepper motor-driven pressure regulating valves, pulse width modulation valves that manage refrigerant flow and pressure-regulating gas cooler/flash gas bypass valves. The use of remote monitoring systems is growing. Not only is remote monitoring a safer option, but it is also in response to the current shortage of trained HVAC technicians, allowing companies to monitor multiple systems and locations with fewer workers.
Overcoming the challenges of R290
With the high flammability of R290, refrigerator manufacturers need to make the necessary system design changes to align with applicable UL and ASHRAE standards that include charge limits, marking requirements and ventilation requirements. System charges of up to 150 grams are currently allowed for most R290 applications, though a few are even lower. Proposed and under-revision UL safety standards seek to raise this limit as high as 500 grams for open refrigeration appliances, and 300 grams for closed appliances. While some systems or applications would remain with more restrictive charges, these increases promise to open R290 to many more applications and enable new applications.
To address flammability concerns, Parker manufactures innovative filter driers and thermostatic expansion valves (TEVs) that are designed to minimize the amount of refrigeration system charge when using flammable refrigerants.that are designed to minimize the amount of refrigeration system charge when using flammable refrigerants.
In addition, some system manufacturers use a sealed design that seals off the spark inside by isolating the R290 from the electrical switch assembly. This type of design reduces the potential for explosion by stopping the gas from entering the electrical switch compartment.
Another option is to fit the leak detection and control systems such that, when activated, it will pump down the propane charge into a liquid receiver and then shut off the electrical supply. If the compressor is enclosed, a ventilation fan must be installed and activated by the leak detection system to remove any gas that might leak from the compressor into the enclosure.
Preparing for an uncertain future
Despite the ongoing changes and obstacles presented by various environmental regulations in the U.S. and abroad, the good news is that the necessary product and material innovations are already available to help engineers overcome the design challenges presented by low-GWP refrigerants, such as CO2 and R290.
This article was contributed by Parker Sporlan Division.
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25 Jun 2021
This Climate Control blog is to review the basic refrigeration cycle and the interaction between the four basic components. The four basic components are the compressor, condenser, expansion device, and evaporator. Let's look at each component and its function and then look at what happens when we do not properly match these components.
Compressor:
The compressor is the transition point from the system's low-pressure side to its high-pressure side. Its purpose is to compress the cool low-pressure gas/vapor at the evaporator pressure up to the condenser pressure. In the compression process, the heat from compression and possibly motor heat increases the gas's temperature. The vapor entering the compressor is also superheated, which further increases during the compression process. At the discharge of the compressor, the refrigerant is a high-temperature, high-pressure superheated gas. Figure 1 below shows the ideal refrigeration cycle graphically on a Pressure-Enthalpy Diagram. The vertical axis is pressure, and the horizontal axis is enthalpy, or the heat content of the refrigerant per pound of refrigerant circulated. The compressor is the sloped line on the right side. The upper horizontal line is the condenser, the lower horizontal line is the evaporator, and the vertical line on the left is the expansion valve. Please note this is an ideal refrigeration diagram. There is no superheat exiting the evaporator or subcooling exiting the condenser. For a more detailed explanation of the P-H diagram, please refer to Sporlan Form 5-200 in our website's literature section under HVACR Educational Material.
Figure 1.
We task the condenser with removing the heat absorbed in the evaporator, the heat of compression, and heat added by the compressor motor (as long as we use a hermetic or semi-hermetic compressor). This heat removal comes in two forms. First, the gas is desuperheated since the gas exiting the compressor increases in temperature above the saturated condensing temperature. Desuperheating is a sensible temperature change that can be measured as a decrease in temperature as the heat is removed from the gas. After the gas is desuperheated, it is in saturated conditions. At this point, additional heat removal condenses the gas into a liquid and is where the condenser gets its name. This heat removal occurs at a constant temperature and pressure until all the gas is condensed into a liquid, referred to as latent heat change. Keep in mind that the pressure is still at the same pressure when it exited the compressor, minus any small pressure loss from flow losses. Also, anytime there is liquid and vapor present, you are in saturated conditions, such as in the condenser or evaporator. You can use a Pressure-Temperature chart to determine the corresponding temperature from the measured pressure. Be aware of the difference and when to use dew point or bubble point when using a blended refrigerant. After the gas completely condenses into a liquid, any additional heat removal results in a temperature drop or sensible heat change. When the temperature drops below the condensing temperature or the saturated condensing temperature, the liquid is subcooled. Subcooling means we cool the refrigerant below the saturated temperature or, in this case, the condensing temperature. Subcooling is beneficial to prevent the refrigerant from flashing or reaching saturated conditions before the expansion device. Flashing can occur due to pressure drop from pressure losses in the tubing and accessories ahead of the expansion device. Any gas bubbles (flashing) can severely affect the TEV flowrate by reducing the refrigerant volume that can pass through the expansion device orifice.
Expansion device:
The expansion device is the transition point from the system's high side to its low side. The expansion device drops the pressure from the high side pressure, referred to as the discharge pressure or condenser pressure, to the low side pressure. You may also refer to the low side pressure as the suction pressure or evaporator pressure. For this example, we use the Thermostatic Expansion Valve (TEV) as the expansion device. Other expansion devices could be a capillary tube, fixed restrictor, automatic expansion valve, or an electric expansion valve. These devices all have their benefits when weighing cost and performance or efficiency. The thermostatic expansion valve or TEV controls the superheat exiting the evaporator. In doing so, it controls the proper amount of refrigerant flows into the evaporator under all load conditions. As the load increases, the superheat increases driving the TEV further open to match the amount of refrigerant boiled off in the evaporator. Vice versa, if the load decreases, the superheat decreases driving the TEV in a more closed position.
Evaporator:
The evaporator is the component that the other components are supporting. The evaporator removes the heat from the space you want to cool, whether it is a walk-in cooler or freezer, supermarket case, or an A/C unit. When the refrigerant leaves the TEV, it is a refrigerant liquid and vapor mixture. The vapor exiting the TEV is due to the refrigerant boiling at the lower pressure and cooling the liquid down to the desired evaporator temperature. When the refrigerant mixture enters the evaporator, it continues to boil at constant pressure and temperature. As it changes from a liquid to a vapor, it absorbs the heat flowing across the evaporator at the desired temperature. Evaporators may also be used as heat sinks to cool computer chips, machinery, or other items.
Matching or mismatching of components:
The secret to an optimally performing refrigeration or air conditioning system is matching all the components to balance the system. If one or more of the components are oversized or undersized, poor performance could result and higher energy costs.
For example, let us start with a 3 ton or 36 MBH(36,000 BTU/hr) system with all the components properly matched for the load. When we match the components correctly, we maintain the desired evaporator temperature at design conditions. Let us analyze what would happen if we replaced the 36 MBH compressor with a 48 MBH compressor, with everything else remaining the same. The first issue is the higher cost for a larger compressor, but we selected a larger compressor in this case. Since the compressor is now larger, the evaporator's pressure with a larger displacement compressor operates at lower suction pressure and lower evaporator temperature. Lower suction pressure results in a compressor that can cause short cycling, higher energy cost, and a shortened compressor life. Lower suction also causes a higher TD (temperature difference) across the evaporator coil, increasing its BTU capacity. It can also result in a different relative humidity than desired and possible coil frosting or icing since the TD is now higher across the coil. The increase in TD also causes an increase in the evaporator capacity and results in a higher flow rate than design through the expansion valve. If not sized for the new compressor, the TEV is not large enough for the system and starves or operates at a higher superheat. The compressor EER or Energy Efficiency Ratio also decreases due to the lower operating suction pressure meaning less BTU removed per Watts of energy consumed.
The result of installing a smaller compressor would be the obvious lower system capacity and not meeting the required design conditions or comfort for space. Also, the TEV would be oversized and could hunt. Also, the evaporator would operate at a higher pressure/temperature resulting in possible poor humidity control.
Moving around the system, if everything else is equal, what happens if the condenser is oversized? The drawbacks to an oversized condenser would be increased system refrigerant charge and increased equipment cost, and possibly operating issues during cold ambient conditions. However, there are benefits to an oversized condenser when properly evaluated by equipment manufacturers. Everyone has noticed that condensers are much larger than in past years on residential air conditioning units. The condensers in these systems have increased in size to meet the new SEER ratings, and a larger condenser helps increase the SEER rating of the system and reduce energy consumption.
An undersized condenser results in higher discharge temperatures, added stress on the compressor, and higher energy cost. It could also cause oil and refrigerant breakdown and result in a premature compressor failure.
It is always wise to properly size the TEV to match the compressor and evaporator capacity. Undersized TEVs starve the evaporator resulting in low suction pressure and poor system performance and temperature control. A starving valve (high superheat) can also cause high discharge temperatures and compressor overheating. An oversized TEV can result in TEV hunting because it overshoots its superheat setpoint due to the oversized valve port. Additionally, a hunting oversized valve could cause flood back to the compressor and damage to the compressor. A hunting valve also causes poor system performance as the valve overfeeds and underfeeds.
Evaporators need to be correctly sized to extract the correct amount of heat to meet the design load. If undersized, they operate at a lower suction pressure affecting/reducing the space's humidity and causing the compressor to operate at a lower pressure than design, resulting in higher energy costs. If oversized, it could result in better energy efficiency, but it could adversely affect the humidity, which could be undesirable if used for comfort cooling. Sizing the evaporator becomes a balancing act like the other components between comfort or desired result and energy efficiency.
Conclusion:
These are just some examples to look for when installing or replacing equipment components. As well as these examples, there are other considerations when diagnosing a system; a change in entering air temperature, relative humidity, outdoor air temperature, dirty filters or condensers, and many other factors. When troubleshooting, look at the basics and check temperatures and pressures. If these numbers are not correct, check and verify what could be influencing the pressures and temperatures.
HVACR Tech Tip Article contributed by Pat Bundy, application engineer, Sporlan Division of Parker Hannifin
Additional HVACR Tech Tips helpful for you:
HVACR Tech Tip: 12 Solutions for Fixing Common TEV Problems
HVACR Tech Tip: Understanding and Preventing Superheat Hunting in TEVs
HVACR Tech Tip: Considering a Refrigeration System Retrofit? Part 1
23 Mar 2021
Annual Walk-in Energy Factor (AWEF) is an energy standard by the Department of Energy (DOE) that measures electrical energy input versus its cooling capacity. All commercial refrigeration equipment manufacturers should comply with the AWEF rating specified by the DOE. HVAC equipment of 3000 ft² or less must conform to this new requirement. All new walk-in installations should be with an AWEF compliant unit. Furthermore, anytime a replacement unit is installed, it needs to comply with AWEF.
There are several ways original equipment manufacturers (OEMs) can achieve the AWEF rating. These include adding an electric expansion valve, oversizing the condenser, on-demand defrost, among others. However, the most economical way to achieve AWEF is to lower or float the system head pressure.
Traditional head pressure settings are anywhere from 180 psig to 295 psig, depending on the system refrigerant. This setting maintains the system's high side temperature and pressure like a summer condition year-round. OEMs are now using head pressures as low as 123 psig for medium-temperature applications and 100 psig for low-temperature applications. This lower head pressure setting significantly impacts expansion valve sizing. In the winter, the cold temperatures allow for more compressor capacity. However, less capacity is available from the expansion valve counteracting the compressor capacity.
An expansion valve's capacity is determined by the liquid temperature and pressure drop available. The colder the liquid temperature, the more available capacity the valve has; the greater the pressure drop, the greater the available capacity. In winter, the expansion valve has a colder liquid temperature, but there is very little pressure drop available to the valve due to reduced head pressure resulting in a much lower available capacity. The result is a larger than expected expansion valve needed in AWEF applications.
In the below example, look at what happens in the system before lowering head pressure. Using R-407A, 100°F condensing temperature (238 psig), 5°F subcooling, and -10°F (15 psig) saturated suction temperature, there is 192 psi available to the valve in this scenario, assuming an appropriately sized distributor with about 31 psi drop across it.
If the head pressure gets floated down to 100 psig, there is much less available capacity. At the colder temperature, the compressor now has approximately 2.7 tons. The cold liquid temperature makes the distributer oversized, so we only get 14 psi across it, resulting in an available pressure drop of 71 psi across the expansion valve.
To counteract this problem and make sizing valves easier for our customers, Parker Sporlan has researched compressor efficiencies, distributor sizing, and valve sizing at the maximum summer condition and the minimum winter condition for AWEF applications. Bulletin 500-10-AWEF provides expansion valve capacity information for AWEF applications. The bulletin helps the contractor and wholesale counter employee to be able to accurately size and select the proper expansion valve for AWEF applications. The values presented in 500-10-AWEF provide maximum and minimum BTU/hr load at the unit's rated condition. Most times, this rating is at 105°F condensing temperature and 96°F liquid temperature. Recommendations in Bulletin 500-10-AWEF are per AHRI 1250. This bulletin helps provide thermostatic expansion valve selections for AWEF applications. Download Parker Sporlan Bulletin 500-10-AWEF.
View how to properly size an expansion valve for a DOE AWEF compliant system in this short video.
HVACR Tech Tip Article contributed by Jason Forshee, application engineer, Sporlan Division of Parker Hannifin
Additional HVACR Tech Tips helpful for you:
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27 Jan 2021
As we introduced our Parker Sporlan webinar series we realized that we couldn't possibly answer all the questions in that short amount of time. We decided to create Climate Control blogs to answer some of the more pressing questions. This is the third of three blogs answering questions from our Supermarket Seminar Series: Metering Devices, TEVs.
Q: What is the minimum pressure difference across the TEV?
A: The existence of pressure-drop helps to facilitate flow through the thermostatic expansion valve or TEV. At some point, flow won’t occur if the pressure drop is too low. Manufacturers will typically provide ratings for expansion valves with a minimum pressure drop of 30 psid across the TEV. This does not include the pressure drop that would occur across the distributor if present in the system and the pressure drop across the evaporator.
Q: The pressure drop across TEV in the Correction Factor table ranges widely, 30 to 275 psig. How does a TXV with a widely varying condensing pressure act, say a freezer that condenses from 150 psig winter to 250 psig summer?
A: The ratings in the capacity tables for Sporlan TEVs are in accordance with ANSI/ARI Standard Number 750. The proper valve selection is critical to offering a good balance of control over the varying conditions. The TEV will ultimately attempt to control superheat at the bulb location even under varying conditions. As conditions vary, a situation may occur that is beyond the ability of the TEV to control superheat at the bulb location. Adjustment or replacement of the TEV may be required. In more extreme cases, there may exist a need for the hot gas bypass to control low side pressures and a head pressure control system to control high side pressures in order to stabilize system conditions. You stack the odds in favor of the TEV being able to control superheat with stable conditions. We recommend using our Virtual Engineer program to properly select valves based on those varying conditions.
Q: We need a TEV rated for R449A, but we don't have it in stock. Could we use a similar TEV rated for R22 as a replacement?
A: The mass flow rate for R449A is 7 to 10% higher compared to R22 depending upon system conditions. The Net Refrigerating Effect (NRE) of R22 is slightly higher compared to R449A as expected. In general, the existing R22 TEV will serve as a suitable replacement for the R449A application; however, this is no guarantee. It is good practice to evaluate the existing components with appropriate selection software or ratings tables using the new system conditions.
Q: In the age of energy savings and reduced head pressure during cool weather conditions, what should we watch out for? How would we detect a problem with the TXV?
A: The TEV is intended to control superheat at the sensing bulb location. Determining the superheat at the bulb location is one way to determine if something is amiss. Careful product selection and system commissioning is ever important today. System monitoring during various conditions is key with these new reductions in head pressure (walk-in coolers, etc.). There are many system parameters that should trigger an alarm condition and ultimately indicate some control problem has occurred. Low or High superheat at the bulb location would be one such condition. Unfortunately, a problem may not be detected until the case is warm and the product has been lost. Utilization of Sporlan’s Virtual Engineer program can assist with proper valve selection and help get things started correctly.
Q: On the MOP charge migration concern, wouldn’t heating the element affect valve function?
A: Yes, it will but in a good way. If the thermostatic charge constituents have all migrated to the diaphragm housing, the TEV will not be operational and it will not be controlling superheat at the bulb location. By warming the diaphragm housing or element, the charge constituents will be forced back into the bulb, once again making the TEV operational. A warm rag on the diaphragm housing can be used to determine if charge migration has occurred. The diaphragm housing should always be warmer than the bulb, especially with MOP-style thermostatic charges.
Q: If hot gas for capacity control is being utilized and introduced before the evaporator, how does that affect the bulb and valve?
A: In this instance, the hot gas will be mixed in the evaporator with the refrigerant being introduced from the TEV. The TEV will simply do its job of controlling superheat at the bulb. It will be influenced by the load on the evaporator and the hot gas that has been introduced at the inlet of the evaporator. In this scenario, the TEV will continue to act as the same superheat control that it did prior to the introduction of the hot gas. However, it will also act as a desuperheating device to temper the discharge gas.
Q: Why don’t manufacturers use bleed ports more often since it helps start the compressor?
A: Good question, maybe we should ask the equipment manufacturers. Bleed Ports are handy for restarting a unit against a pressure differential, for fine-tuning TEV capacity, for maintaining minimum suction pressure during startups when the system is equipped with a micro-channel condenser and the list continues. However, bleed ports prevent TEVs from seating tightly and this can complicate the ratings process for manufacturers.
Q: Why do compressor manufacturers generally expect a higher superheat at the compressor inlet as compared to the evaporator outlet?
A: The TEV is intended to control superheat at the sensing bulb location. As the superheated refrigerant travels through the suction line on the way to the compressor inlet, ambient conditions can contribute to the superheat of the refrigerant. This can happen if the suction line is uninsulated or if it is routed through high-temperature areas on the job site. This becomes a balancing act. Too little superheat at the compressor inlet and a flooded condition may damage the compressor. Too much superheat and the compressor may overheat.
For more information on TEVs see Parker Sporlan Bulletin 10-10-8, Bulletin 10-9, Bulletin 10-10.
For more information on Parker Sporlan products please visit our website.
Article contributed by Jim Jansen, senior application engineer, Sporlan Division of Parker Hannifin
Additional resources on HVACR Tech Tips:
Parker Sporlan Supermarket Seminar Series: Metering Devices, TEVs - Q&A Part 1
Parker Sporlan Supermarket Seminar Series: Metering Devices, TEVs - Q&A Part 2
HVACR Tech Tip: Understanding and Preventing Superheat Hunting in TEVs
4 Nov 2020
ZoomLock MAX press-to-connect flame-free refrigerant fittings help to improve productivity for HVACR contractors and technicians on the job. Having the ZoomLock MAX complete system equipped with all the sizes and configurations you will need simply saves time and improves safety and efficiency.
This post is the last blog in our series providing answers to the top FAQs on ZoomLock MAX. The Q & As cover refrigerants and oils, and installation technicalities for fittings, leaks, sealing, temperature, and system compatibility.
Applications
ZoomLock MAX fittings are designed for the following applications:
Refrigeration
Air Conditioning
Heat Pump (Refrigeration Side)
Download the full list of FAQs in this handy guide and learn more about ZoomLock MAX.
Q: What approved refrigerants are for use with ZoomLock MAX?
A: ZoomLock MAX is approved for use with R-32, R-134a, R-404A, R-407C, R-407F, R-410A, R-507, R1234ze, R1234yf, R-718, R-450A, R-513A, R-448A, R-449A, R-407A, R-427A, R-438A, R-417A and R-422D.
A: Use ZoomLock MAX for approved POE, PAO, PVE, AB, and mineral oils. The O-ring has been tested successfully with PAG oil; however, you should not use PAG oil with copper systems due to the potential for corrosion of the copper material.
A: No, if a pressed fitting is leaking, the fitting must be cut out and replaced. You should not attempt to braze the fitting as you may melt the O-ring material and thus introduce contaminants into the system that could cause other system issues.
A: No, ZoomLock MAX has been thoroughly freeze/thaw tested.
A: No, ZoomLock MAX has been Acid Salt Spray tested to ASTM G85. As with all copper installations, avoid exposure to ammonia.
A: Yes, the O-ring does compensate for small/minor scratches on the surface of the tube. However, avoid imperfections adjacent to the crimp area such as scratches, incise marks, and tubing that is not round. Reference copper piping standard for roundness.
A: If you use ZoomLock MAX in an application that the fitting goes beyond the specified limits of the O-ring, then there is an increased likelihood that a leak can occur due to the compromised O-ring.
A: ZoomLock MAX fittings comply with the cleanliness standards as required in the Copper Tube Standards EN 12735-1 and ASTM-B280. Keep the zip closure bag sealed to protect fittings from contamination.
A: Vibration is a recognized cause of leaks, design the system, and install to comply with all local standards and codes of practice, which aim to minimize vibration. Extensively tested ZoomLock MAX fittings ensure the joint doesn’t leak as a result of system vibration and complies with the following standards:
ISO 14903, Temperature Pressure Cycling and Vibration Test
UL 109 - 8, Vibration Test
UL 207, Fatigue Shock Test
A: Good installation practice, a nitrogen purge during any brazing (not required with ZoomLock MAX mechanical fittings), a deep evacuation, and the proper installation and use of filter-driers containing new and effective molecular sieve desiccants prevent many system failures including the buildup of acid within the system. When selecting which desiccant material is best for an application, consider water capacity, refrigerant and lubricant compatibility, acid capacity, and physical strength, which are essential characteristics of desiccants.
A: No, some rotational movement is quite acceptable, the joint will not leak, nor will it come apart under the pressure loading and during system operation. Some joint movement is good and allows for expansion and contraction in the system pipework.
A: No, ZoomLock MAX is not suitable for medical gas applications.
A: No, only press ZoomLock MAX fittings once.
A: No, do not use ZoomLock MAX for drinking water systems.
A: No, use ZoomLock MAX for air conditioning and refrigeration applications only.
A: Pull 200 microns for a deep vacuum.
Improved productivity equates to more profitability for your business
ZoomLock MAX technology is the next generation of the press–to–connect copper refrigeration and air conditioning fittings—and flameless connections. Now, HVACR professionals can safely make secure leak-free connections in seconds without the use of a brazing torch or press tool. Adding all that time savings allow for more scheduled jobs and greater profitability potential for your business.
Ready to learn more? Visit the ZoomLock MAX website to download the full FAQs sheet, schedule a demo, watch it in action, get training support, locate a distributor, and get started today!
Article contributed by Chris Reeves, product manager, Contaminant Control Products, Sporlan Division of Parker Hannifin. For more information on Parker Sporlan products please visit our website.
Related, helpful content for you:
ZoomLock MAX Press-to-Connect Refrigerant Fittings FAQs–Part 1
ZoomLock MAX Press-to-Connect Refrigerant Fittings FAQs– Part 2
HVACR Tech Tip: What Every Technician Needs to Know About Refrigeration Oils
HVACR Tech Tip: Guide to Servicing Blended Refrigerants
Parker Sporlan Supermarket Seminar Series: Metering Devices, TEVs - Q&A Part 1
8 Oct 2020
ZoomLock MAX press-to-connect refrigerant fittings are changing the way HVACR professionals connect refrigerant lines. By using ZoomLock MAX, you, the HVACR technician can connect refrigerant lines in seconds, boosting efficiency while providing the safety and reliability you expect from Parker.
This post is the second in our series providing answers to the top FAQs on ZoomLock MAX fittings. The answers cover crimping, jaws, tools, and compliance.
Applications
ZoomLock MAX fittings are designed for the following applications:
Refrigeration
Air Conditioning
Heat Pump (Refrigeration Side)
Download the full list of FAQs in this handy guide and learn more about ZoomLock MAX.
Q: Where do I crimp ZoomLock MAX fittings?
A: Crimp with the jaw straddling directly over the O-ring section of the fitting, as in the image below.
Q: How many crimps can you complete on a complete battery charge?
A: That is tool dependent; consult the tool manufacturers owner’s manual.
Q: How do you know when to service the tool?A: That is tool dependent; consult the tool manufactures owner’s manual.
Q: What is the expected life of the jaws?A: ZoomLock MAX jaws are laser hardened and have a finite life expectancy. We encourage each customer to have the jaws and tools serviced and checked annually or every 10,000 crimps depending on which comes first.
Q: What tool manufacturers and models are ZoomLock MAX jaws compatible?A: Please refer to the Press Tool Compatibility table below.
A: Check jaws at the latest one year after the purchase or after 10,000 pressings (according to whichever occurs first) by an authorized Rothenberger testing center. Repeat these checks at the latest one year or another 10,000 pressings after the previous inspection. During jaw inspection, check the jaws for operating and functional safety and wear parts (e.g., springs). Functionally and operationally safe jaws are returned.
Q: Where can replacement batteries and chargers be purchased?A: That is tool dependent; check the tool manufacturer owner’s manual.
Q: Can you use ZoomLock MAX to crimp to aluminum, steel, or stainless steel?A: ZoomLock MAX is designed explicitly for copper to copper connections.
Q: What standards and codes is ZoomLock MAX compliant with, and what approvals does it hold?UL Listed: Refrigerant fitting SA7511.
UL Listed: Approved use for field and factory installations.
UL 109 - 7 Pull test is compliant.
UL 109 - 8 Vibration test is compliant.
UL 1963 - 79 Tests of Gaskets and Seals used in Refrigerant Systems compliant.
ISO 5149-2:2014, Refrigerating systems, and heat pumps - Safety and environmental requirements - Part 2: Design, construction, testing, marking and documentation, compliant.
ISO 5149-2 - 5.3.2.2.3 Strength pressure test is compliant.
ISO 14903 - 7.4 Tightness test is compliant.
ISO 14903 - 7.6 Pressure temperature vibration tests (PTV) compliant.
ISO 14903 - 7.8 Freezing test is compliant.
ASTM G85 -11 Standard Practice for Modified Salt Spray (Fog) Testing compliant.
ASHRAE 15 - 2016 Safety Standard for Refrigeration Systems compliant.
ASME B31.5 - 2016 Refrigeration Piping and Heat Transfer Components compliant.
2018, 2015 - 2012, 2009, and 2006 International Mechanical Code (IMC), certified ICC-ES, PMG-1440.
2018, 2015, 2012, 2009 and 2006 International Residential Code (IRC), certified ICC-ES, PMG-1440.
2018, 2015, 2012, 2009, and 2006 Uniform Mechanical Code (UMC), certified, ICC-ES, PMG-1440.
A: Yes, ZoomLock MAX is a press fitting system for use with hard, half-hard, or annealed copper tube conforming to EN12735-1 or ASTM-B280.
Q: What is the guarantee on ZoomLock MAX fittings?A: The product has a 10-year guarantee from the first date of purchase.
Q: What is the material used to make the O-ring?A: Hydrogenated Nitrile Butadiene Rubber (HNBR).
Q: What is the expected life of the O-ring in the system?A: The expected life of the O-ring, if used within the product specifications for temperature and pressure, is at least 25 years. The product has a 10-year guarantee from the first date of purchase.
Q: Are there any storage issues, including where the fittings are stored in vehicles and exposed to extremes of high or low temperature?A: No, the product is not subject to degradation under normal storage conditions, provided it is kept in original packaging and not exposed to direct sunlight for long periods.
The time-saving solution for HVACR technicians and contractors
ZoomLock MAX technology provides a leak-proof connection, eliminating brazing, flames, fire spotters, or risks from installing traditional HVACR fittings. Now, HVACR technicians and contractors can install piping in seconds with NO torch, NO hot work permits, and NO fire safety equipment.
Ready to learn more? Visit the ZoomLock MAX website to download the full FAQs sheet, schedule a demo, watch it in action, get training support, locate a distributor, and get started today!
Article contributed by Chris Reeves, product manager, Contaminant Control Products, Sporlan Division of Parker Hannifin. For more information on Parker Sporlan products please visit our website.
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25 Sep 2020
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