Installation seting Adjusung Superheat sd ulb positioning are for proper operation of an evaporator, and for compressor protectio Superheat Problems stopRddlnandiadtePr are countless possible cause Expans lective superheat is low(lower than 57, there is a potential for flooding n a wide range of applications. refrigerant back to the compressor. If superheat is higher than 15"c, suse it is very easy to get to Low refrigerant charge, resulting an fash gas in the evaporator is probab r-dror in before adjusting superheat. Improper systam dasign, resulting in little or no iNYou Leed to dust TELystoresIsan you have aurra E Evaporator Characteristcs wabu kaaba2 TEV Installation The TEV must be installed in the liquid line, ahead of the evaporator and as close to it as possible. The bulb is tightly strapped to the suction line, as close to the evaporator outlet as possible. The bulb will give false signals to the diaphragm if it is installed after a desuperheater or close to components with large mass, such as large valves or flange connections. Any evaporator with a distributor or with a significant pressure drop requires an externally equalized TEV. If the valve is externally equalized, the equalizing line must be connected, otherwise the valve will not operate. The equalization connection is made at a point in the suction line immediately after the bulb, and in a 12 o’clock position on the tube to avoid oil logging the equalizer line. Mount the TEV’s sensing bulb on a horizontal suction line tube at the outlet of the evaporator in a position between 12 and 4 o’clock. The location depends on the suction line diameter. Tubes smaller than 3/4 in. should have the bulb located at the 12 or 1 o’clock position; ¾- and 7/8- in. tubes require a bulb position at 2 o’clock; for tubes 1 in. and larger, the correct position is from 3 to 4 o’clock. Never locate the bulb at the bottom of the suction line because of the possibility of a false signal caused by oil lying there. For the same reason, the bulb must not be mounted in areas where the suction line is bent and may act as an oil trap, as on a riser. Remember that the optimum location is on a horizontal part of the suction line immediately after the evaporator outlet. The bulb must have good thermal contact with the suction line. (Danfoss valves with double-contact bulbs improve thermal conduction.) The bulb mounting strap transfers heat to the area of the bulb that is not in contact with the copper tubing. Never use plastic straps such as cable ties for bulb mounting. Time and temperature will loosen the plastic material; contact as well as heat transfer will be lost. The bulb mounting strap supplied by TEV manufacturers is made of heat-conductive material, and should always be tight, but not so tight as to deform the piping or bulb. Although not a requirement, if heat-conductive paste is available, you can use it on the contact surfaces to enhance heat transfer. Because it needs to be able to sense the temperature of superheated suction vapor, the bulb must not be located in a position where external heat or cold will affect it. Insulating the bulb will help, but in cases where the lines operate below 32? the insulating material must be chosen to seal against moisture that might freeze around the bulb. Insulation of the bulb is also recommended if the bulb is exposed to a warm air current. On systems where a liquid distributor is used, remember that the TEV must be externally equalized, and the distributor should be mounted vertically, head outlets downward. It is extremely important that the feeder tubes from the distributor be of the same diameter and length. It is important to keep pressure drops across the distributor tubes as equal as possible for good liquid distribution. Avoid liquid traps when routing the distributor tubing. Piping must be carefully designed and executed to prevent any unwanted effects. For instance, where a circuit has multiple evaporators at different elevations, a higher evaporator can affect the TEV sensing bulb on a lower one. Also, in multi-fixture circuits, you may find situations where another technician has mislocated a sensing bulb so that it is actually reading the temperature of the common suction line rather than the evaporator it is meant to serve. Setting, Adjusting Superheat All expansion valves are supplied with a factory superheat setting appropriate for most applications. TEVs with fixed superheat do not allow readjustment in the field. Other valves, though, are designed to allow field setting by adjusting the spring force. To adjust the static superheat, turn the valve’s setting stem. Turning clockwise increases static superheat and effectively reduces refrigerant flow through the valve. Turning counterclockwise reduces static superheat and increases refrigerant flow. In addition to TEV sizing, correct superheat setting and proper sensing bulb positioning are two more of the many important determining factors for proper operation of an evaporator, and for compressor protection. The bulb will give false signals to the diaphragm if it is installed after a desuperheater or close to components with large mass, such as large valves or flange connections. Superheat Problems Expansion valves are often suspected of causing system problems. But generally speaking, a TEV is operating properly if it maintains superheat of 5?to 15? If superheat is low (lower than 5?, there is a potential for flooding refrigerant back to the compressor. If superheat is higher than 15°C, the evaporator is probably operating inefficiently. Stop Fiddling and Find the Problem There are countless possible causes for problems in a system. Superheat is one of the last things we adjust. Expansion valves are designed and set by their manufacturers to serve as “plug-and-play” devices which, right out of the box, can operate effectively in a wide range of applications. The temptation to adjust them is there because it is very easy to get to them before taking time to properly diagnose the refrigeration system. Unless there is absolute certainty of incorrect superheat, leave the TEV alone. Here are some problem areas that can cause low and high superheat. These areas should be investigated before adjusting superheat. Causes of low superheat include: · An improperly adjusted valve; · A significantly oversized valve; · Poor bulb or equalizer location; · Overcharged system; and · Excessive oil blocking the evaporator and acting as an insulator. Causes of high superheat include: · Low refrigerant charge, resulting in flash gas in the liquid line; · Dirt in the system trapped in the valve; · A restriction such as a plugged filter-drier in the liquid line, again causing flash gas; · A saturated or undersized drier in the system; unremoved moisture is likely to result in the formation of ice, restricting the TEV’s orifice; and · Improper system design, resulting in little or no liquid subcooling. If You Need to Adjust Earlier we talked about the proper way to take a superheat reading. If the valve is adjustable, and if you determine that the superheat needs to be set (for example, because the system is hunting), prepare for the adjustment by ensuring that you have operational head pressure and a proper flow of refrigerant to the TEV, without flash gas. Next, ensure that there is a nominal (or design) load on the evaporator; use a dummy load if necessary. Now remove the stem cap to expose the adjustment stem. Setting superheat is a trial-and-error procedure that will require several changes. 1. Adjust the valve to a point where you get unstable superheat readings, unless you have confirmed that the system has unstable superheat to begin with. (When superheat is unstable, the system is out of control and temperature and pressure are randomly fluctuating.) 2. Proceed to adjust the valve by turning the valve stem clockwise to increase superheat until the system is just stable. Then a further one-quarter to one-half turn clockwise will compensate for system variables during operation. 3. The valve manufacturer’s instructions give the number of stem turns per degree of superheat. You need to measure superheat after each adjustment, until the new value results in correct evaporator temperature under the nominal (or design) load. 4. Recheck the superheat under low-load conditions, too. Now you can be sure that the valve is set correctly. When there’s a refrigeration problem, don’t start working on a remedy before making a careful diagnosis. Adjusting superheat without careful observation and measurement is asking for trouble. The same goes for pumping down a system to replace the expansion valve, only to find out that the system is still not working. It wastes time and can be rather embarrassing. But some systematic troubleshooting, examining system pressures and temperatures, will likely lead to a solid diagnosis, a timely solution, and a satisfied customer. TEV Hysteresis and Evaporator Characteristics