Trane TRG-TRC013-EN manuel d'utilisation

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Table des matières du manuel d’utilisation

  • Page 1

    Air Conditioning Clinic Air Conditioning Fans One of the Equipment Series TRG-TRC013-EN 85667_Cvr.fm Page 1 Friday, October 8, 1999 10:05 AM[...]

  • Page 2

    NO POST AGE NECESSARY IF MAILED IN THE UNITED ST A TES BUSINES S REPL Y MAIL FIRST -CLAS S MAIL PERMIT NO. 11 LA CROS SE, WI POST AGE WILL BE P AID BY ADDRESSEE THE TRANE COMP ANY Attn: Applications Engineering 3600 P ammel Creek Road La Crosse WI 54601-9985 NO POST AGE NECESSARY IF MAILED IN THE UNITED ST A TES BUSINES S REPL Y MAIL FIRST -CLAS S [...]

  • Page 3

    P erforation 5.625” from top P erforation 3.25” from left edge Comment Card We want to ensure that our educational materials meet your ever -changing resource development needs. Please take a moment to comment on the effectiveness of this Air Conditioning Clinic. Air Conditioning Fans Level of detail (circle one) T oo basic Just right T oo diff[...]

  • Page 4

    Air Conditioning Fans One of the Equipment Series A publication of The T rane Company— W orldwide Applied Systems Group[...]

  • Page 5

    Preface © 1999 American Standard Inc. All rights reserved TRG-TRC013-EN ii The T rane Company believes that it is incumbent on manufacturers to serve the industry by regularly disseminating information gathered through laboratory research, testing programs, and field experience. The T rane Air Conditioning Clinic series is one means of knowledge s[...]

  • Page 6

    TRG-TRC013-EN iii Contents Introduction ........................................................... 1 period one Fan Performance .................................................. 2 Fan Performance Curves ....................................... 11 System Resistance Curve ...................................... 17 Fan – System Interaction .........[...]

  • Page 7

    iv TRG-TRC013-EN[...]

  • Page 8

    TRG-TRC013-EN 1 notes Introduction Efficient distribution of conditioned air needed to heat, cool, and ventilate a building requires the service of a properly selected and applied fan. The types of fans commonly used in HV AC applications include centrifugal and axial designs. In a centrifugal fan the airflow follows a radial path through the fan w[...]

  • Page 9

    2 TRG-TRC013-EN notes period one Fan Performance Compared to compressors, the pressures generated by these air -moving devices within the ductwork of HV AC systems are relatively small. The measurement of these pressures is, however , essential to the determination of fan performance. One instrument that is available to measure these small pressure[...]

  • Page 10

    TRG-TRC013-EN 3 period one Fan Performance notes When the pressure within the ductwork is positive, that is, greater than atmospheric, the water column is forced downward in the closed leg and forced upward in the open leg. Conversely , a negative pressure within the ductwork causes the water column to drop in the open leg and to rise in the closed[...]

  • Page 11

    4 TRG-TRC013-EN notes period one Fan Performance Since some of the pressures observed in air conditioning systems are very small, the U-tube has been modified to improve the ability to read such small differences in water levels. The modification replaces one leg of the tube with a liquid reservoir and the other leg with an inclined tube. This inst[...]

  • Page 12

    TRG-TRC013-EN 5 period one Fan Performance notes The total amount of pressure generated by a fan has two components: velocity pressure and static pressure. The velocity pressure is due to the momentum of the air as it moves axially through the duct, while the static pressure is due to the perpendicular outward “push” of the air against the duct[...]

  • Page 13

    6 TRG-TRC013-EN notes period one Fan Performance With the fan operating and the damper fully open, air moves through the duct unimpeded. The impact of the moving air causes the vane to swing in the direction of airflow . The pressure exerted on the vane is due to the velocity of the air moving through the duct, not the static pressure exerted on th[...]

  • Page 14

    TRG-TRC013-EN 7 period one Fan Performance notes This build-up of static pressure results in reduced air velocity (velocity pressure) and therefore a reduction in the airflow delivered by the fan. Notice that the hinged vane has moved toward a more vertical position. The reduced velocity pressure on the face of the vane causes it to move to a more [...]

  • Page 15

    8 TRG-TRC013-EN notes period one Fan Performance Another probe can be placed in the duct with its open end facing into the air stream. This probe senses total pressure — the combination of velocity pressure plus static pressure. Therefore, static pressure can be read directly , while velocity pressure is derived by subtracting the static pressure[...]

  • Page 16

    TRG-TRC013-EN 9 period one Fan Performance notes The characteristics of a fan’ s performance under various duct pressure conditions is tested by an apparatus similar to the one shown here. The fan is connected to a long piece of straight duct with a throttling device at the end. The throttling device is used to change the air resistance of the du[...]

  • Page 17

    10 TRG-TRC013-EN notes period one Fan Performance Next, the measured velocity pressure is used to calculate the airflow delivered by the fan. The manometer measures the velocity pressure (P v ) by subtracting static pressure (P s ) from total pressure (P t ). Next, the air velocity (V) can be calculated by dividing velocity pressure (P v ) by the a[...]

  • Page 18

    TRG-TRC013-EN 11 period one Fan Performance notes Fan Performance Curves This point can then be plotted on a chart that has static pressure on the vertical axis and airflow on the horizontal axis. Additional data from the fan tests establish other static pressure and corresponding airflow performance points for a given rotational speed (revolutions[...]

  • Page 19

    12 TRG-TRC013-EN notes period one Fan Performance When a series of points is plotted, a curve can be drawn. The resulting curve graphically illustrates the performance of this fan when it is operated at a constant speed. Notice that the curve extends from blocked-tight static pressure, with a corresponding zero airflow , to wide-open airflow , with[...]

  • Page 20

    TRG-TRC013-EN 13 period one Fan Performance notes Next, the fan laws are used to calculate the performance characteristics of this same fan at other rotational speeds. The subscript 1 refers to the tested performance conditions; the subscript 2 refers to the calculated performance conditions. The result is a family of curves that represents the spe[...]

  • Page 21

    14 TRG-TRC013-EN notes period one Fan Performance Finally , using the measurements from the dynamometer and the fan laws, curves can be calculated and plotted to represent the fan’ s power consumption at each operating condition. When most fans approach the blocked-tight static-pressure condition, instability is encountered. This condition is kno[...]

  • Page 22

    TRG-TRC013-EN 15 period one Fan Performance notes A surge line is established during the fan test procedure to indicate the area on a fan performance curve where surge occurs. As long as the fan’ s operating point falls to the right of this line, the fan will operate in a stable manner . If the fan is operated at a point that falls to the left of[...]

  • Page 23

    16 TRG-TRC013-EN notes period one Fan Performance Fan manufacturers may present their performance data in graphical and/or tabular form. Similar to using the fan curve, by knowing the desired airflow and pressure-producing capability of the fan, the table can be used to determine the fan’ s speed and input power requirement. For example, assume a[...]

  • Page 24

    TRG-TRC013-EN 17 period one Fan Performance notes System Resistance Curve Now that a typical fan performance curve has been developed, let’ s see how the fan will perform within a system. With each airflow , an air distribution system imposes a certain resistance to the passage of air . The resistance is the sum of all of the pressure losses expe[...]

  • Page 25

    18 TRG-TRC013-EN notes period one Fan Performance Assuming the system does not change, the static-pressure loss due to the system varies with the square of the airflow . Other points on the system resistance curve are determined by using the following fan law equation: For example, when the same system is delivering 2,000 cfm [0.94 m 3 /s], the sta[...]

  • Page 26

    TRG-TRC013-EN 19 period one Fan Performance notes By plotting several such points, a curve can be established. This system resistance curve represents the static pressure that the fan must generate, at various airflows, to overcome the resistance — or static-pressure loss — within this particular system. Fan – System Interaction By superimpos[...]

  • Page 27

    20 TRG-TRC013-EN notes period one Fan Performance Consider a case where the air resistance through the system is greater than predicted. Instead of the design operating point A , the actual system resistance curve intersects the fan performance curve at B , delivering a lower airflow than intended. The solution to this problem is to either improve [...]

  • Page 28

    TRG-TRC013-EN 21 period one Fan Performance notes Reducing the fan speed causes the system resistance and fan performance curves to intersect at E . The fan delivers the design airflow at a lower static pressure, with less power required. In these examples, it was possible to compensate for the inaccuracies in estimated system resistance through fa[...]

  • Page 29

    22 TRG-TRC013-EN notes period one Fan Performance Let’ s assume that the fan from the previous example, delivering 3,500 cfm [1.65 m 3 /s] at 2.0 in. H 2 O [491 Pa] of static pressure, requires 2.0 hp [1.5 kW] of input power . At these conditions, the fan’ s static efficiency would be: Static Efficiency 3,500 cfm × 2.0 in. H 2 O 6,362 × 2.0 h[...]

  • Page 30

    TRG-TRC013-EN 23 period one Fan Performance notes In a constant-volume system, where the fan is always delivering the same airflow , the fan is generally selected to balance the airflow and static-pressure requirements at a point on the fan curve that permits a certain margin of safety before surge occurs. As the coil and filters become dirty , the[...]

  • Page 31

    24 TRG-TRC013-EN notes period one Fan Performance The fan performance curves discussed so far are typical of both the centrifugal and fixed-pitch vaneaxial fans. T o complete the discussion, the fan performance curves of the variable-pitch vaneaxial (VPV A) fan will be reviewed. While this type of fan operates at a constant speed, the pitch (angle)[...]

  • Page 32

    TRG-TRC013-EN 25 period one Fan Performance notes Unlike the previous fan performance curves, those of the VPV A fan are plotted on the basis of airflow , at various blade pitches, versus total pressure (static pressure plus velocity pressure). This type of fan generates high air velocities and, therefore, high velocity pressures. T o fully evaluat[...]

  • Page 33

    26 TRG-TRC013-EN notes period one Fan Performance Similar to both the centrifugal and fixed-pitch vaneaxial fans, the intersection of the system resistance curve and the blade pitch curve establishes the airflow and total pressure at which this fan and this system will balance. While the system design conditions are typically stated in terms of sta[...]

  • Page 34

    TRG-TRC013-EN 27 notes The most common types of fans used in air conditioning applications are the centrifugal and axial designs. In a centrifugal fan the airflow enters the center of the fan from the side and follows a radial path through the fan wheel. There are three principal types of centrifugal fans, each distinguished by the type of fan whee[...]

  • Page 35

    28 TRG-TRC013-EN notes period two Fan T ypes Forward Curved (FC) Fans The first of these centrifugal fan wheels to be considered has blades that are curved in the direction of wheel rotation. These are called forward curved , or FC, fans. FC fans are operated at relatively low speeds and are used to deliver large volumes of air against relatively l[...]

  • Page 36

    TRG-TRC013-EN 29 period two Fan T ypes notes The static pressure produced by a fan is a function of the forward motion of the air at the blade tip. The FC fan can perform, within its airflow and static pressure range, at lower rotational speeds than other types of fans. The typical application range of this type of fan is from 30 to 80 percent wide[...]

  • Page 37

    30 TRG-TRC013-EN notes period two Fan T ypes Notice how the fan input-power lines cross the FC fan performance curves. If the system resistance were to drop, the actual system resistance curve would also drop, moving the operating point ( A ) to a higher airflow ( B ). At the same time, the fan’ s input power requirement would also rise, possibly[...]

  • Page 38

    TRG-TRC013-EN 31 period two Fan T ypes notes The angle of the backward inclined blade causes the air leaving the wheel to bend back against the direction of rotation. However , the speed of wheel rotation ( S ) causes the air to assume a velocity ( V ) in the direction shown. Comparing the performance of FC and BI fans, for a given wheel speed ( S [...]

  • Page 39

    32 TRG-TRC013-EN notes period two Fan T ypes The application range of the BI fan is from approximately 40 to 85 percent wide-open airflow . As before, an operating point below 40 percent wide open may place the fan in surge and an operating point above 85 percent wide open typically produces noise and inefficiency . The maximum static efficiency of[...]

  • Page 40

    TRG-TRC013-EN 33 period two Fan T ypes notes A variation of this type of fan, called the backward curved (BC) fan, uses a slight curve in the fan blades, away from the direction of rotation. The performance characteristics of the BC fan are similar to those of the BI fan. Airfoil (AF) Fans A refinement of the BI fan changes the shape of the blade f[...]

  • Page 41

    34 TRG-TRC013-EN notes period two Fan T ypes The application range of the airfoil fan is from approximately 50 to 85 percent wide-open airflow . This is a narrower application range than either the FC or BI fan. The reason is that the airfoil fan surges at a greater percentage of wide-open airflow , placing the surge line farther to the right on th[...]

  • Page 42

    TRG-TRC013-EN 35 period two Fan T ypes notes V aneaxial Fans In an axial fan, the airflow passes straight through the fan, parallel to the shaft. There are three common axial fan types: propeller , tubeaxial, and vaneaxial. Propeller fans are well suited for high volumes of air , but have little or no static-pressure generating capability . T ubeax[...]

  • Page 43

    36 TRG-TRC013-EN notes period two Fan T ypes The application range of the vaneaxial fan is from approximately 60 to 90 percent wide-open airflow . Similar to the BI and AF fans, the input power lines are essentially parallel to the fan performance curves, and therefore the vaneaxial fan is considered a nonoverloading type of fan. Static efficiencie[...]

  • Page 44

    TRG-TRC013-EN 37 period two Fan T ypes notes The VPV A fan is selected so that the operating point is within the most efficient area of the performance curves. T otal efficiencies from 60 to 84 percent are possible with the VPV A fan. Again, total efficiency is calculated by substituting total pressure for static pressure in the static efficiency e[...]

  • Page 45

    38 TRG-TRC013-EN notes period two Fan T ypes The selection of the type of fan to be used in a particular application is based on the system size and space availability . The forward curved fan is best applied in small systems requiring 20,000 cfm [9.4 m 3 /s] or less and static pressures of 4 in. H 2 O [996 Pa] or less. The FC fan is also the least[...]

  • Page 46

    TRG-TRC013-EN 39 notes period three Fan Capacity Control The previous discussions assumed that the fan would perform at a single operating point, located by the intersection of the system resistance and fan performance curves, in a constant-volume system. This type of system provides a constant volume of variable-temperature air to control the envi[...]

  • Page 47

    40 TRG-TRC013-EN notes period three Fan Capacity Control This modulation causes the actual system resistance curve to shift. In a V A V system, therefore, the fan no longer operates at a single point on its performance curve but must operate over a range of such points. “Riding the Fan Curve” The simplest form of fan capacity control is called [...]

  • Page 48

    TRG-TRC013-EN 41 period three Fan Capacity Control notes This method of fan modulation can be used with any type of fan. It is most effective, however , when applied to FC fans. The configuration of the input power curves of the FC fan are such that its power requirement drops as the fan operating point moves upward along the constant-speed perform[...]

  • Page 49

    42 TRG-TRC013-EN notes period three Fan Capacity Control Because of this issue, and since many V A V systems are large with high static pressures, some form of system static-pressure control is generally used. A V A V system’ s static-pressure requirement consists of a fixed component and a variable component. The system requires a minimum amount[...]

  • Page 50

    TRG-TRC013-EN 43 period three Fan Capacity Control notes An exaggerated example is used to illustrate this system operation. Assume that the load on the system decreases, causing all or some of the V A V terminal units to modulate closed. This causes the system resistance curve to shift upwards. In response, the fan begins to “ride up” its cons[...]

  • Page 51

    44 TRG-TRC013-EN notes period three Fan Capacity Control There are four methods used to actively control the capacity of a fan. They are discharge dampers, inlet vanes, fan-speed control, and variable-pitch blade control. Discharge Dampers The first method to be discussed is the use of discharge dampers . Discharge dampers match the airflow and sta[...]

  • Page 52

    TRG-TRC013-EN 45 period three Fan Capacity Control notes As the V A V terminal units modulate shut, the system resistance curve shifts upward. The fan begins to “ride up” its constant-speed performance curve toward B , from the design operating point A , trying to balance with this new system resistance curve. As a result, the fan delivers a lo[...]

  • Page 53

    46 TRG-TRC013-EN notes period three Fan Capacity Control Inlet V anes The next method of capacity control, inlet vanes , modulates a fan’ s capacity by “preswirling” the air in the direction of fan rotation before it enters the fan wheel. By changing the air’ s angle of entry into the fan, the modulating inlet vanes lessen the ability of th[...]

  • Page 54

    TRG-TRC013-EN 47 period three Fan Capacity Control notes As the V A V terminal units modulate shut, the system resistance curve shifts upward. The fan begins to “ride up” its current vane position curve toward B , from the design operating point A , trying to balance with this new system resistance curve. As a result, the fan delivers a lower a[...]

  • Page 55

    48 TRG-TRC013-EN notes period three Fan Capacity Control Fan-Speed Control The third method of capacity control, fan-speed control , modulates fan capacity by varying the speed of the wheel rotation. This is commonly accomplished using a variable-speed device on the fan motor , such as a variable-frequency drive, a belt-speed changer , a variable-s[...]

  • Page 56

    TRG-TRC013-EN 49 period three Fan Capacity Control notes along the V A V system modulation curve and the fan satisfies the system static-pressure controller . The low end of the fan’ s modulation range is limited by the surge region. The principal advantages of fan-speed control are its energy saving potential and reduced noise at part load. V ar[...]

  • Page 57

    50 TRG-TRC013-EN notes period three Fan Capacity Control The performance and control of the direct-drive, variable-pitch vaneaxial (VPV A) fan is similar to that of a fan equipped with inlet vanes. Again, as the system resistance curve shifts upward and the fan begins to “ride up” the current blade pitch curve toward B , from its design operati[...]

  • Page 58

    TRG-TRC013-EN 51 period three Fan Capacity Control notes These curves describe the performance characteristics of various methods of fan capacity control, in terms of the input power required versus the percent of design airflow . Realize that these are generalized curves based on a given set of test conditions. Generally , the forward-curved (FC) [...]

  • Page 59

    52 TRG-TRC013-EN notes period four Application Considerations Several considerations must be addressed when applying fans in air conditioning systems, including: ■ System static-pressure control ■ System effect ■ Acoustics ■ Effect of actual (nonstandard) conditions on fan selection ■ Equipment certification standards While not all-inclus[...]

  • Page 60

    TRG-TRC013-EN 53 period four Application Considerations notes System Static-Pressure Control Fan capacity control requires a signal from a controller , which monitors static pressure using a sensor located somewhere in the supply duct system. This controller compares the sensed pressure to a set point and modulates the fan capacity to maintain the [...]

  • Page 61

    54 TRG-TRC013-EN notes period four Application Considerations Another method of static-pressure control, the optimized static-pressure control method, positions a single static-pressure sensor near the fan outlet. The static-pressure controller dynamically adjusts the static-pressure set point based on the position of the modulating dampers, or val[...]

  • Page 62

    TRG-TRC013-EN 55 period four Application Considerations notes System Effect At the end of Period One, we discussed the effect of the air resistance through the system being greater than predicted. This is often caused by failing to allow for the effects of the fan connections to the duct system. This system effect can be attributed to turbulence du[...]

  • Page 63

    56 TRG-TRC013-EN notes period four Application Considerations the fan outlet, this system effect should be accounted for in the fan selection. If an elbow , turning vanes, air straightener , or other obstruction is located too close to the fan inlet, this system effect should also be accounted for in the fan selection. Additionally , the effects of[...]

  • Page 64

    TRG-TRC013-EN 57 period four Application Considerations notes An HV AC system can be made quieter by reducing the source (fan) sound level and/or increasing the attenuation of the path. In many cases, fan selection is very important to the final sound level. Smaller , higher-speed fans often create more noise then larger , lower-speed, and slightly[...]

  • Page 65

    58 TRG-TRC013-EN notes period four Application Considerations Effect of Actual (Nonstandard) Conditions Most fan performance data is published at standard air conditions, which are basically sea level elevation and 70 °F [21 °C]. If the airflow requirement for a given application is stated at nonstandard conditions, a density correction must be m[...]

  • Page 66

    TRG-TRC013-EN 59 period four Application Considerations notes Equipment Certification Standards The Air Movement and Control Association (AMCA) establishes testing procedures and rating standards for air -moving devices. AMCA also certifies performance and labels equipment through programs that involve random testing of a manufacturer’ s equipmen[...]

  • Page 67

    60 TRG-TRC013-EN notes Let’ s review the main concepts that were covered in this clinic on air conditioning fans. Period One introduced the method of determining and plotting fan performance. It also discussed static pressure versus velocity pressure and the interaction of the fan and the system. Air Conditioning Fans period five Figure 85 Review[...]

  • Page 68

    TRG-TRC013-EN 61 period five Review notes Period T wo introduced the various fan types, including forward curved (FC), backward inclined (BI), airfoil (AF), and vaneaxial. Period Three presented various methods for controlling fan capacity , including “riding the fan curve,” discharge dampers, inlet vanes, variable fan-speed control, and variab[...]

  • Page 69

    62 TRG-TRC013-EN notes period five Review Period Four covered several considerations in the application of fans in air conditioning systems, including system static-pressure control, system effect, acoustics, the effect of actual (nonstandard) conditions on fan selection, and equipment certification standards. Revie w—Period Four ▲ Application [...]

  • Page 70

    TRG-TRC013-EN 63 period five Review notes For more information, refer to the following references: ■ Fans and their Application in Air Conditioning (T rane literature order number ED-F AN) ■ T rane Air Conditioning Manual ■ “V A V System Optimization” (T rane Engineers Newsletter , 1991–volume 20, number 2) ■ “Specifying ‘Quality [...]

  • Page 71

    64 TRG-TRC013-EN Questions for Period 1 1 The total pressure generated by the fan is made up of two components, __________ pressure and __________ pressure. 2 The total pressure (P t ) measured within a duct is 3.5 in. H 2 O [872 Pa] and the static pressure (P s ) is 3 in. H 2 O [747 Pa]. Assume the air is at standard conditions, ρ = 0.0749 lb/ft [...]

  • Page 72

    TRG-TRC013-EN 65 Quiz 6 Between the forward curved (FC) and backward inclined (BI) fans, which one can handle higher static-pressure applications? 7 Explain why the forward curved (FC) fan is called an overloading type of fan. Questions for Period 3 8 List three methods of fan capacity control. 9 What method of fan capacity control “preswirls” [...]

  • Page 73

    66 TRG-TRC013-EN 1 velocity pressure and static pressure 2a P v = 0.5 in. H 2 O [125 Pa] b V = 2,832 fpm [14.4 m/s] c Airflow = 4,248 cfm [2 m 3 /s] 3a airflow b static pressure c fan speed (rpm) d input power 4 surge 5 forward curved (FC), backward inclined (BI) or backward curved (BC), and airfoil (AF) or plug (plenum) 6 backward inclined (BI) 7 [...]

  • Page 74

    TRG-TRC013-EN 67 adjustable-frequency drive (AFD) See variable-speed drive. airfoil (AF) A type of centrifugal fan that is similar to the backward inclined fan, with the exception that the fan blades are in the shape of an airfoil, like an airplane wing. AMCA Air Movement and Control Association ARI Air -Conditioning & Refrigeration Institute A[...]

  • Page 75

    68 TRG-TRC013-EN Glossary fan-speed control A method of controlling fan capacity by varying its speed of rotation — commonly accomplished using a variable-speed drive on the fan motor . forward curved (FC) A type of centrifugal fan with blades curved in the direction of wheel rotation. inlet vanes A device used to control the capacity of a fan by[...]

  • Page 76

    TRG-TRC013-EN 69 Glossary notes total efficiency The percentage of input power that is realized as useful work in terms of total energy (pressure). total pressure Sum of the velocity pressure plus static pressure. tubeaxial fan A type of axial fan consisting of a propeller fan mounted in a cylinder . vaneaxial fan A type of axial fan with vane-type[...]

  • Page 77

    The T rane Company Worldwide Applied Systems Group 3600 Pammel Creek Road La Crosse, WI 54601-7599 www .trane.com An American Standard Company Literature Order Number TRG-TRC013-EN File Number E/A V -FND-TRG-TRC013-1099-EN Supersedes 2803-9-285 Stocking Location Inland-La Crosse Since The T rane Company has a policy of continuous product improvemen[...]