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Subpart F--Equipment 25.1301 Function and installation. 25.1321 Arrangement and visibility. Electrical Systems and Equipment 25.1351 General. 25.1381 Instrument lights. 25.1411 General. 25.1431 Electronic equipment. |
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Each item of installed equipment must-- (a) Be of a kind and design appropriate to its intended function; (b) Be labeled as to its identification, function, or operating limitations, or any applicable combination of these factors; (c) Be installed according to limitations specified for that equipment; and (d) Function properly when installed. Sec. 25.1303 Flight and navigation instruments. (a) The following flight and navigation instruments must be installed so that the instrument is visible from each pilot station: (1) A free air temperature indicator or an air-temperature indicator which provides indications that are convertible to free-air temperature. (2) A clock displaying hours, minutes, and seconds with a sweep-second pointer or digital presentation. (3) A direction indicator (nonstabilized magnetic compass). (b) The following flight and navigation instruments must be installed at each pilot station: (1) An airspeed indicator. If airspeed limitations vary with altitude, the indicator must have a maximum allowable airspeed indicator showing the variation of VMO with altitude. (2) An altimeter (sensitive). (3) A rate-of-climb indicator (vertical speed). (4) A gyroscopic rate-of-turn indicator combined with an integral slip-skid indicator (turn-and-bank indicator) except that only a slip-skid indicator is required on large airplanes with a third attitude instrument system useable through flight attitudes of 360 deg. of pitch and roll and installed in accordance with Sec. 121.305(j) of this title. (5) A bank and pitch indicator (gyroscopically stabilized). (6) A direction indicator (gyroscopically stabilized, magnetic or nonmagnetic). (c) The following flight and navigation instruments are required as prescribed in this paragraph: (1) A speed warning device is required for turbine engine powered airplanes and for airplanes with VMO/MMO greater than 0.8 VDF/MDF or 0.8 V D/MD. The speed warning device must give effective aural warning (differing distinctively from aural warnings used for other purposes) to the pilots, whenever the speed exceeds VMO plus 6 knots or MMO +0.01. The upper limit of the production tolerance for the warning device may not exceed the prescribed warning speed. (2) A machmeter is required at each pilot station for airplanes with compressibility limitations not otherwise indicated to the pilot by the airspeed indicating system required under paragraph (b)(1) of this section. [Amdt. 25-23, 35 FR 5678, Apr. 8, 1970, as amended by Amdt. 25-24, 35 FR 7108, May 6, 1970; Amdt. 25-38, 41 FR 55467, Dec. 20, 1976] Sec. 25.1305 Powerplant instruments. The following are required powerplant instruments: (a) For all airplanes. (1) A fuel pressure warning means for each engine, or a master warning means for all engines with provision for isolating the individual warning means from the master warning means. (2) A fuel quantity indicator for each fuel tank. (3) An oil quantity indicator for each oil tank. (4) An oil pressure indicator for each independent pressure oil system of each engine. (5) An oil pressure warning means for each engine, or a master warning means for all engines with provision for isolating the individual warning means from the master warning means. (6) An oil temperature indicator for each engine. (7) Fire-warning indicators. (8) An augmentation liquid quantity indicator (appropriate for the manner in which the liquid is to be used in operation) for each tank. (b) For reciprocating engine-powered airplanes. In addition to the powerplant instruments required by paragraph (a) of this section, the following powerplant instruments are required: (1) A carburetor air temperature indicator for each engine. (2) A cylinder head temperature indicator for each air-cooled engine. (3) A manifold pressure indicator for each engine. (4) A fuel pressure indicator (to indicate the pressure at which the fuel is supplied) for each engine. (5) A fuel flowmeter, or fuel mixture indicator, for each engine without an automatic altitude mixture control. (6) A tachometer for each engine. (7) A device that indicates, to the flight crew (during flight), any change in the power output, for each engine with-- (i) An automatic propeller feathering system, whose operation is initiated by a power output measuring system; or (ii) A total engine piston displacement of 2,000 cubic inches or more. (8) A means to indicate to the pilot when the propeller is in reverse pitch, for each reversing propeller. (c) For turbine engine-powered airplanes. In addition to the powerplant instruments required by paragraph (a) of this section, the following powerplant instruments are required: (1) A gas temperature indicator for each engine. (2) A fuel flowmeter indicator for each engine. (3) A tachometer (to indicate the speed of the rotors with established limiting speeds) for each engine. (4) A means to indicate, to the flight crew, the operation of each engine starter that can be operated continuously but that is neither designed for continuous operation nor designed to prevent hazard if it failed. (5) An indicator to indicate the functioning of the powerplant ice protection system for each engine. (6) An indicator for the fuel strainer or filter required by Sec. 25.997 to indicate the occurrence of contamination of the strainer or filter before it reaches the capacity established in accordance with Sec. 25.997(d). (7) A warning means for the oil strainer or filter required by Sec. 25.1019, if it has no bypass, to warn the pilot of the occurrence of contamination of the strainer or filter screen before it reaches the capacity established in accordance with Sec. 25.1019(a)(2). (8) An indicator to indicate the proper functioning of any heater used to prevent ice clogging of fuel system components. (d) For turbojet engine powered airplanes. In addition to the powerplant instruments required by paragraphs (a) and (c) of this section, the following powerplant instruments are required: (1) An indicator to indicate thrust, or a parameter that is directly related to thrust, to the pilot. The indication must be based on the direct measurement of thrust or of parameters that are directly related to thrust. The indicator must indicate a change in thrust resulting from any engine malfunction, damage, or deterioration. (2) A position indicating means to indicate to the flight crew when the thrust reversing device is in the reverse thrust position, for each engine using a thrust reversing device. (3) An indicator to indicate rotor system unbalance. (e) For turbopropeller-powered airplanes. In addition to the powerplant instruments required by paragraphs (a) and (c) of this section, the following powerplant instruments are required: (1) A torque indicator for each engine. (2) Position indicating means to indicate to the flight crew when the propeller blade angle is below the flight low pitch position, for each propeller. (f) For airplanes equipped with fluid systems (other than fuel) for thrust or power augmentation, an approved means must be provided to indicate the proper functioning of that system to the flight crew. [Amdt. 25-23, 35 FR 5678, Apr. 8, 1970, as amended by Amdt. 25-35, 39 FR 1831, Jan. 15, 1974; Amdt. 25-36, 39 FR 35461, Oct. 1, 1974; Amdt. 25-38, 41 FR 55467, Dec. 20, 1976; Amdt. 25-54, 45 FR 60173, Sept. 11, 1980; Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1307 Miscellaneous equipment. The following is required miscellaneous equipment: (a) [Reserved] (b) Two or more independent sources of electrical energy. (c) Electrical protective devices, as prescribed in this part. (d) Two systems for two-way radio communications, with controls for each accessible from each pilot station, designed and installed so that failure of one system will not preclude operation of the other system. The use of a common antenna system is acceptable if adequate reliability is shown. (e) Two systems for radio navigation, with controls for each accessible from each pilot station, designed and installed so that failure of one system will not preclude operation of the other system. The use of a common antenna system is acceptable if adequate reliability is shown. [Amdt. 25-23, 35 FR 5678, Apr. 8, 1970, as amended by Amdt. 25-46, 43 FR 50598, Oct. 30, 1978; Amdt. 25-54, 45 FR 60173, Sept. 11, 1980; Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1309 Equipment, systems, and installations. (a) The equipment, systems, and installations whose functioning is required by this subchapter, must be designed to ensure that they perform their intended functions under any foreseeable operating condition. (b) The airplane systems and associated components, considered separately and in relation to other systems, must be designed so that-- (1) The occurrence of any failure condition which would prevent the continued safe flight and landing of the airplane is extremely improbable, and (2) The occurrence of any other failure conditions which would reduce the capability of the airplane or the ability of the crew to cope with adverse operating conditions is improbable. (c) Warning information must be provided to alert the crew to unsafe system operating conditions, and to enable them to take appropriate corrective action. Systems, controls, and associated monitoring and warning means must be designed to minimize crew errors which could create additional hazards. (d) Compliance with the requirements of paragraph (b) of this section must be shown by analysis, and where necessary, by appropriate ground, flight, or simulator tests. The analysis must consider-- (1) Possible modes of failure, including malfunctions and damage from external sources. (2) The probability of multiple failures and undetected failures. (3) The resulting effects on the airplane and occupants, considering the stage of flight and operating conditions, and (4) The crew warning cues, corrective action required, and the capability of detecting faults. (e) Each installation whose functioning is required by this subchapter, and that requires a power supply, is an "essential load" on the power supply. The power sources and the system must be able to supply the following power loads in probable operating combinations and for probable durations: (1) Loads connected to the system with the system functioning normally. (2) Essential loads, after failure of any one prime mover, power converter, or energy storage device. (3) Essential loads after failure of-- (i) Any one engine on two-engine airplanes; and (ii) Any two engines on three-or-more-engine airplanes. (4) Essential loads for which an alternate source of power is required by this chapter, after any failure or malfunction in any one power supply system, distribution system, or other utilization system. (f) In determining compliance with paragraphs (e) (2) and (3) of this section, the power loads may be assumed to be reduced under a monitoring procedure consistent with safety in the kinds of operation authorized. Loads not required in controlled flight need not be considered for the two-engine inoperative condition on airplanes with three or more engines. (g) In showing compliance with paragraphs (a) and (b) of this section with regard to the electrical system and equipment design and installation, critical environmental conditions must be considered. For electrical generation, distribution, and utilization equipment required by or used in complying with this chapter, except equipment covered by Technical Standard Orders containing environmental test procedures, the ability to provide continuous, safe service under foreseeable environmental conditions may be shown by environmental tests, design analysis, or reference to previous comparable service experience on other aircraft. [Amdt. 25-23, 35 FR 5679, Apr. 8, 1970, as amended by Amdt. 25-38, 41 FR 55467, Dec. 20, 1976; Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1316 System lightning protection. (a) For functions whose failure would contribute to or cause a condition that would prevent the continued safe flight and landing of the airplane, each electrical and electronic system that performs these functions must be designed and installed to ensure that the operation and operational capabilities of the systems to perform these functions are not adversely affected when the airplane is exposed to lightning. (b) For functions whose failure would contribute to or cause a condition that would reduce the capability of the airplane or the ability of the flightcrew to cope with adverse operating conditions, each electrical and electronic system that performs these functions must be designed and installed to ensure that these functions can be recovered in a timely manner after the airplane is exposed to lightning. (c) Compliance with the lightning protection criteria prescribed in paragraphs (a) and (b) of this section must be shown for exposure to a severe lightning environment. The applicant must design for and verify that aircraft electrical/electronic systems are protected against the effects of lightning by: (1) Determining the lightning strike zones for the airplane; (2) Establishing the external lightning environment for the zones; (3) Establishing the internal environment; (4) Identifying all the electrical and electronic systems that are subject to the requirements of this section, and their locations on or within the airplane; (5) Establishing the susceptibility of the systems to the internal and external lightning environment; (6) Designing protection; and (7) Verifying that the protection is adequate. [Amdt. 25-80, 59 FR 22116, Apr. 28, 1994] |
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(a) Each flight, navigation, and powerplant instrument for use by any pilot must be plainly visible to him from his station with the minimum practicable deviation from his normal position and line of vision when he is looking forward along the flight path. (b) The flight instruments required by Sec. 25.1303 must be grouped on the instrument panel and centered as nearly as practicable about the vertical plane of the pilot's forward vision. In addition-- (1) The instrument that most effectively indicates attitude must be on the panel in the top center position; (2) The instrument that most effectively indicates airspeed must be adjacent to and directly to the left of the instrument in the top center position: (3) The instrument that most effectively indicates altitude must be adjacent to and directly to the right of the instrument in the top center position; and (4) The instrument that most effectively indicates direction of flight must be adjacent to and directly below the instrument in the top center position. (c) Required powerplant instruments must be closely grouped on the instrument panel. In addition-- (1) The location of identical powerplant instruments for the engines must prevent confusion as to which engine each instrument relates; and (2) Powerplant instruments vital to the safe operation of the airplane must be plainly visible to the appropriate crewmembers. (d) Instrument panel vibration may not damage or impair the accuracy of any instrument. (e) If a visual indicator is provided to indicate malfunction of an instrument, it must be effective under all probable cockpit lighting conditions. [Amdt. 25-23, 35 FR 5679, Apr. 8, 1970, as amended by Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1322 Warning, caution, and advisory lights. If warning, caution or advisory lights are installed in the cockpit, they must, unless otherwise approved by the Administrator, be-- (a) Red, for warning lights (lights indicating a hazard which may require immediate corrective action); (b) Amber, for caution lights (lights indicating the possible need for future corrective action); (c) Green, for safe operation lights; and (d) Any other color, including white, for lights not described in paragraphs (a) through (c) of this section, provided the color differs sufficiently from the colors prescribed in paragraphs (a) through (c) of this section to avoid possible confusion. [Amdt. 25-38, 41 FR 55467, Dec. 20, 1976] Sec. 25.1323 Airspeed indicating system. For each airspeed indicating system, the following apply: (a) Each airspeed indicating instrument must be approved and must be calibrated to indicate true airspeed (at sea level with a standard atmosphere) with a minimum practicable instrument calibration error when the corresponding pitot and static pressures are applied. (b) Each system must be calibrated to determine the system error (that is, the relation between IAS and CAS) in flight and during the accelerated takeoff ground run. The ground run calibration must be determined-- (1) From 0.8 of the minimum value of V1 to the maximum value of V2, considering the approved ranges of altitude and weight; and (2) With the flaps and power settings corresponding to the values determined in the establishment of the takeoff path under Sec. 25.111 assuming that the critical engine fails at the minimum value of V1. (c) The airspeed error of the installation, excluding the airspeed indicator instrument calibration error, may not exceed three percent or five knots, whichever is greater, throughout the speed range, from-- (1) VMO to 1.3 VS1, with flaps retracted; and (2) 1.3 VS0 to VFE with flaps in the landing position. (d) Each system must be arranged, so far as practicable, to prevent malfunction or serious error due to the entry of moisture, dirt, or other substances. (e) Each system must have a heated pitot tube or an equivalent means of preventing malfunction due to icing. (f) Where duplicate airspeed indicators are required, their respective pitot tubes must be far enough apart to avoid damage to both tubes in a collision with a bird. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-57, 49 FR 6849, Feb. 23, 1984] Sec. 25.1325 Static pressure systems. (a) Each instrument with static air case connections must be vented to the outside atmosphere through an appropriate piping system. (b) Each static port must be designed and located in such manner that the static pressure system performance is least affected by airflow variation, or by moisture or other foreign matter, and that the correlation between air pressure in the static pressure system and true ambient atmospheric static pressure is not changed when the airplane is exposed to the continuous and intermittent maximum icing conditions defined in Appendix C of this part. (c) The design and installation of the static pressure system must be such that-- (1) Positive drainage of moisture is provided; chafing of the tubing and excessive distortion or restriction at bends in the tubing is avoided; and the materials used are durable, suitable for the purpose intended, and protected against corrosion; and (2) It is airtight except for the port into the atmosphere. A proof test must be conducted to demonstrate the integrity of the static pressure system in the following manner: (i) Unpressurized airplanes. Evacuate the static pressure system to a pressure differential of approximately 1 inch of mercury or to a reading on the altimeter, 1,000 feet above the airplane elevation at the time of the test. Without additional pumping for a period of 1 minute, the loss of indicated altitude must not exceed 100 feet on the altimeter. (ii) Pressurized airplanes. Evacuate the static pressure system until a pressure differential equivalent to the maximum cabin pressure differential for which the airplane is type certificated is achieved. Without additional pumping for a period of 1 minute, the loss of indicated altitude must not exceed 2 percent of the equivalent altitude of the maximum cabin differential pressure or 100 feet, whichever is greater. (d) Each pressure altimeter must be approved and must be calibrated to indicate pressure altitude in a standard atmosphere, with a minimum practicable calibration error when the corresponding static pressures are applied. (e) Each system must be designed and installed so that the error in indicated pressure altitude, at sea level, with a standard atmosphere, excluding instrument calibration error, does not result in an error of more than +/-30 feet per 100 knots speed for the appropriate configuration in the speed range between 1.3 VS0 with flaps extended and 1.8 VS1 with flaps retracted. However, the error need not be less than +/-30 feet. (f) If an altimeter system is fitted with a device that provides corrections to the altimeter indication, the device must be designed and installed in such manner that it can be bypassed when it malfunctions, unless an alternate altimeter system is provided. Each correction device must be fitted with a means for indicating the occurrence of reasonably probable malfunctions, including power failure, to the flight crew. The indicating means must be effective for any cockpit lighting condition likely to occur. (g) Except as provided in paragraph (h) of this section, if the static pressure system incorporates both a primary and an alternate static pressure source, the means for selecting one or the other source must be designed so that-- (1) When either source is selected, the other is blocked off; and (2) Both sources cannot be blocked off simultaneously. (h) For unpressurized airplanes, paragraph (g)(1) of this section does not apply if it can be demonstrated that the static pressure system calibration, when either static pressure source is selected, is not changed by the other static pressure source being open or blocked. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-5, 30 FR 8261, June 29, 1965; Amdt. 25-12, 32 FR 7587, May 24, 1967; Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1326 Pitot heat indication systems. If a flight instrument pitot heating system is installed, an indication system must be provided to indicate to the flight crew when that pitot heating system is not operating. The indication system must comply with the following requirements: (a) The indication provided must incorporate an amber light that is in clear view of a flight crewmember. (b) The indication provided must be designed to alert the flight crew if either of the following conditions exist: (1) The pitot heating system is switched "off". (2) The pitot heating system is switched "on" and any pitot tube heating element is inoperative. [Amdt. 25-43, 43 FR 10339, Mar. 13, 1978] Sec. 25.1327 Magnetic direction indicator. (a) Each magnetic direction indicator must be installed so that its accuracy is not excessively affected by the airplane's vibration or magnetic fields. (b) The compensated installation may not have a deviation, in level flight, greater than 10 degrees on any heading. Sec. 25.1329 Automatic pilot system. (a) Each automatic pilot system must be approved and must be designed so that the automatic pilot can be quickly and positively disengaged by the pilots to prevent it from interfering with their control of the airplane. (b) Unless there is automatic synchronization, each system must have a means to readily indicate to the pilot the alignment of the actuating device in relation to the control system it operates. (c) Each manually operated control for the system must be readily accessible to the pilots. (d) Quick release (emergency) controls must be on both control wheels, on the side of each wheel opposite the throttles. (e) Attitude controls must operate in the plane and sense of motion specified in Secs. 25.777(b) and 25.779(a) for cockpit controls. The direction of motion must be plainly indicated on, or adjacent to, each control. (f) The system must be designed and adjusted so that, within the range of adjustment available to the human pilot, it cannot produce hazardous loads on the airplane, or create hazardous deviations in the flight path, under any condition of flight appropriate to its use, either during normal operation or in the event of a malfunction, assuming that corrective action begins within areasonable period of time. (g) If the automatic pilot integrates signals from auxiliary controls or furnishes signals for operation of other equipment, there must be positive interlocks and sequencing of engagement to prevent improper operation. Protection against adverse interaction of integrated components, resulting from a malfunction, is also required. (h) If the automatic pilot system can be coupled to airborne navigation equipment, means must be provided to indicate to the flight crew the current mode of operation. Selector switch position is not acceptable as a means of indication. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-46, 43 FR 50598, Oct. 30, 1978] Sec. 25.1331 Instruments using a power supply. (a) For each instrument required by Sec. 25.1303(b) that uses a power supply, the following apply: (1) Each instrument must have a visual means integral with, the instrument, to indicate when power adequate to sustain proper instrument performance is not being supplied. The power must be measured at or near the point where it enters the instruments. For electric instruments, the power is considered to be adequate when the voltage is within approved limits. (2) Each instrument must, in the event of the failure of one power source, be supplied by another power source. This may be accomplished automatically or by manual means. (3) If an instrument presenting navigation data receives information from sources external to that instrument and loss of that information would render the presented data unreliable, the instrument must incorporate a visual means to warn the crew, when such loss of information occurs, that the presented data should not be relied upon. (b) As used in this section, "instrument" includes devices that are physically contained in one unit, and devices that are composed of two or more physically separate units or components connected together (such as a remote indicating gyroscopic direction indicator that includes a magnetic sensing element, a gyroscopic unit, an amplifier and an indicator connected together). [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1333 Instrument systems. For systems that operate the instruments required by Sec. 25.1303(b) which are located at each pilot's station-- (a) Means must be provided to connect the required instruments at the first pilot's station to operating systems which are independent of the operating systems at other flight crew stations, or other equipment; (b) The equipment, systems, and installations must be designed so that one display of the information essential to the safety of flight which is provided by the instruments, including attitude, direction, airspeed, and altitude will remain available to the pilots, without additional crewmember action, after any single failure or combination of failures that is not shown to be extremely improbable; and (c) Additional instruments, systems, or equipment may not be connected to the operating systems for the required instruments, unless provisions are made to ensure the continued normal functioning of the required instruments in the event of any malfunction of the additional instruments, systems, or equipment which is not shown to be extremely improbable. [Amdt. 25-23, 35 FR 5679, Apr. 8, 1970, as amended by Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1335 Flight director systems. If a flight director system is installed, means must be provided to indicate to the flight crew its current mode of operation. Selector switch position is not acceptable as a means of indication. [Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1337 Powerplant instruments. (a) Instruments and instrument lines. (1) Each powerplant and auxiliary power unit instrument line must meet the requirements of Secs. 25.993 and 25.1183. (2) Each line carrying flammable fluids under pressure must-- (i) Have restricting orifices or other safety devices at the source of pressure to prevent the escape of excessive fluid if the line fails; and (ii) Be installed and located so that the escape of fluids would not create ahazard. (3) Each powerplant and auxiliary power unit instrument that utilizes flammable fluids must be installed and located so that the escape of fluid would not create a hazard. (b) Fuel quantity indicator. There must be means to indicate to the flight crewmembers, the quantity, in gallons or equivalent units, of usable fuel in each tank during flight. In addition-- (1) Each fuel quantity indicator must be calibrated to read "zero" during level flight when the quantity of fuel remaining in the tank is equal to the unusable fuel supply determined under Sec. 25.959; (2) Tanks with interconnected outlets and airspaces may be treated as one tank and need not have separate indicators; and (3) Each exposed sight gauge, used as a fuel quantity indicator, must be protected against damage. (c) Fuel flowmeter system. If a fuel flowmeter system is installed, each metering component must have a means for bypassing the fuel supply if malfunction of that component severely restricts fuel flow. (d) Oil quantity indicator. There must be a stick gauge or equivalent means to indicate the quantity of oil in each tank. If an oil transfer or reserve oil supply system is installed, there must be a means to indicate to the flight crew, in flight, the quantity of oil in each tank. (e) Turbopropeller blade position indicator. Required turbopropeller blade position indicators must begin indicating before the blade moves more than eight degrees below the flight low pitch stop. The source of indication must directly sense the blade position. (f) Fuel pressure indicator. There must be means to measure fuel pressure, in each system supplying reciprocating engines, at a point downstream of any fuel pump except fuel injection pumps. In addition-- (1) If necessary for the maintenance of proper fuel delivery pressure, there must be a connection to transmit the carburetor air intake static pressure to the proper pump relief valve connection; and (2) If a connection is required under paragraph (f)(1) of this section, the gauge balance lines must be independently connected to the carburetor inlet pressure to avoid erroneous readings. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as
amended by Amdt. 25-40, 42 FR 15044, Mar. 17, 1977] |
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(a) Electrical system capacity. The required generating capacity, and number and kinds of power sources must-- (1) Be determined by an electrical load analysis; and (2) Meet the requirements of Sec. 25.1309. (b) Generating system. The generating system includes electrical power sources, main power busses, transmission cables, and associated control, regulation, and protective devices. It must be designed so that-- (1) Power sources function properly when independent and when connected in combination; (2) No failure or malfunction of any power source can create a hazard or impair the ability of remaining sources to supply essential loads; (3) The system voltage and frequency (as applicable) at the terminals of all essential load equipment can be maintained within the limits for which the equipment is designed, during any probable operating condition; and (4) System transients due to switching, fault clearing, or other causes do not make essential loads inoperative, and do not cause a smoke or fire hazard. (5) There are means accessible, in flight, to appropriate crewmembers for the individual and collective disconnection of the electrical power sources from the system. (6) There are means to indicate to appropriate crewmembers the generating system quantities essential for the safe operation of the system, such as the voltage and current supplied by each generator. (c) External power. If provisions are made for connecting external power to the airplane, and that external power can be electrically connected to equipment other than that used for engine starting, means must be provided to ensure that no external power supply having a reverse polarity, or a reverse phase sequence, can supply power to the airplane's electrical system. (d) Operation without normal electrical power. It must be shown by analysis, tests, or both, that the airplane can be operated safely in VFR conditions, for a period of not less than five minutes, with the normal electrical power (electrical power sources excluding the battery) inoperative, with critical type fuel (from the standpoint of flameout and restart capability), and with the airplane initially at the maximum certificated altitude. Parts of the electrical system may remain on if- (1) A single malfunction, including a wire bundle or junction box fire, cannot result in loss of both the part turned off and the part turned on; and (2) The parts turned on are electrically and mechanically isolated from the parts turned off. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-41, 42 FR 36970, July 18, 1977; Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1353 Electrical equipment and installations. (a) Electrical equipment, controls, and wiring must be installed so that operation of any one unit or system of units will not adversely affect the simultaneous operation of any other electrical unit or system essential to the safe operation. (b) Cables must be grouped, routed, and spaced so that damage to essential circuits will be minimized if there are faults in heavy current-carrying cables. (c) Storage batteries must be designed and installed as follows: (1) Safe cell temperatures and pressures must be maintained during any probable charging or discharging condition. No uncontrolled increase in cell temperature may result when the battery is recharged (after previous complete discharge)-- (i) At maximum regulated voltage or power; (ii) During a flight of maximum duration; and (iii) Under the most adverse cooling condition likely to occur in service. (2) Compliance with paragraph (c)(1) of this section must be shown by test unless experience with similar batteries & installations has shown that maintaining safe cell temperatures & pressures presents no problem. (3) No explosive or toxic gases emitted by any battery in normal operation, or as the result of any probable malfunction in the charging system or battery installation, may accumulate in hazardous quantities within the airplane. (4) No corrosive fluids or gases that may escape from the battery may damage surrounding airplane structures or adjacent essential equipment. (5) Each nickel cadmium battery installation capable of being used to start an engine or auxiliary power unit must have provisions to prevent any hazardous effect on structure or essential systems that may be caused by the maximum amount of heat the battery can generate during a short circuit of the battery or of its individual cells. (6) Nickel cadmium battery installations capable of being used to start an engine or auxiliary power unit must have-- (i) A system to control the charging rate off the battery automatically s as to prevent battery overheating; (ii) A battery temperature sensing and over-temperature warning system with ameans for disconnecting the battery from its charging source in the event of an over-temperature condition; or (iii) A battery failure sensing and warning system with a means for disconnecting the battery from its charging source in the event of battery failure. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-41, 42 FR 36970, July 18, 1977; Amdt. 25-42, 43 FR 2323, Jan. 16, 1978] Sec. 25.1355 Distribution system. (a) The distribution system includes the distribution busses, their associated feeders, and each control and protective device. (b) [Reserved] (c) If two independent sources of electrical power for particular equipment or systems are required by this chapter, in the event of the failure of one power source for such equipment or system, another power source (including its separate feeder) must be automatically provided or be manually selectable to maintain equipment or system operation. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-23, 35 FR 5679, Apr. 8, 1970; Amdt. 25-38, 41 FR 55468, Dec. 20, 1976] Sec. 25.1357 Circuit protective devices. (a) Automatic protective devices must be used to minimize distress to the electrical system and hazard to the airplane in the event of wiring faults or serious malfunction of the system or connected equipment. (b) The protective and control devices in the generating system must be designed to de-energize and disconnect faulty power sources and power transmission equipment from their associated busses with sufficient rapidity to provide protection from hazardous over-voltage and other malfunctioning. (c) Each resettable circuit protective device must be designed so that, when an overload or circuit fault exists, it will open the circuit irrespective of the position of the operating control. (d) If the ability to reset a circuit breaker or replace a fuse is essential to safety in flight, that circuit breaker or fuse must be located and identified so that it can be readily reset or replaced in flight. (e) Each circuit for essential loads must have individual circuit protection. However, individual protection for each circuit in an essential load system (such as each position light circuit in a system) is not required. (f) If fuses are used, there must be spare fuses for use in flight equal to at least 50 percent of the number of fuses of each rating required for complete circuit protection. (g) Automatic reset circuit breakers may be used as integral protectors for electrical equipment (such as thermal cut-outs) if there is circuit protection to protect the cable to the equipment. Sec. 25.1359 [Removed. 55 FR 29785, July 20, 1990] EDITORIAL NOTE: For the convenience of the user, the removed text is set out below. Sec. 25.1359 Electrical system fire and smoke protection. (a) Components of the electrical system must meet the applicable fire and smoke protection requirements of Secs. 25.831(c), 25.863, and 25.867. (b) Electrical cables, terminals, and equipment in designated fire zones, that are used during emergency procedures, must be at least fire-resistant. (c) Main power cables (including generator cables) in the fuselage must be designed to allow a reasonable degree of deformation and stretching without failure and must-- (1) Be isolated from flammable fluid lines; or (2) Be shrouded by means of electrically insulated flexible conduit, or equivalent, which is in addition to the normal cable insulation. (d) Insulation on electrical wire and electrical cable installed in any area of the fuselage must be self-extinguishing when tested at an angle of 60 deg. in accordance with the applicable portions of Appendix F of this part, or other approved equivalent methods. The average burn length may not exceed 3inches and the average flame time after removal of the flame source may not exceed 30 seconds. Drippings from the test specimen may not continue to flame for more than an average of 3 seconds after falling. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-17, 33 FR 9066, June 20, 1968; Amdt. 25-32, 37 FR 3972, Feb. 24, 1972; Amdt. 25-57, 49 FR 6849, Feb. 23, 1984] Sec. 25.1363 Electrical system tests. (a) When laboratory tests of the electrical system are conducted-- (1) The tests must be performed on a mock-up using the same generating equipment used in the airplane; (2) The equipment must simulate the electrical characteristics of the distribution wiring and connected loads to the extent necessary for valid test results; and (3) Laboratory generator drives must simulate the actual prime movers on the airplane with respect to their reaction to generator loading, including loading due to faults. (b) For each flight condition that cannot be simulated
adequately in the laboratory or by ground tests on the
airplane, flight tests must be made. |
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(a) The instrument lights must-- (1) Provide sufficient illumination to make each instrument, switch and other device necessary for safe operation easily readable unless sufficient illumination is available from another source; and (2) Be installed so that-- (i) Their direct rays are shielded from the pilot's eyes; and (ii) No objectionable reflections are visible to the pilot. (b) Unless undimmed instrument lights are satisfactory under each expected flight condition, there must be a means to control the intensity of illumination. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1383 Landing lights. (a) Each landing light must be approved, and must be installed so that-- (1) No objectionable glare is visible to the pilot; (2) The pilot is not adversely affected by halation; and (3) It provides enough light for night landing. (b) Except when one switch is used for the lights of a multiple light installation at one location, there must be a separate switch for each light. (c) There must be a means to indicate to the pilots when the landing lights are extended. Sec. 25.1385 Position light system installation. (a) General. Each part of each position light system must meet the applicable requirements of this section and each system as a whole must meet the requirements of Secs. 25.1387 through 25.1397. (b) Forward position lights. Forward position lights must consist of a red and a green light spaced laterally as far apart as practicable and installed forward on the airplane so that, with the airplane in the normal flying position, the red light is on the left side and the green light is on the right side. Each light must be approved. (c) Rear position light. The rear position light must be a white light mounted as far aft as practicable on the tail or on each wing tip, and must be approved. (d) Light covers and color filters. Each light cover or color filter must be at least flame resistant and may not change color or shape or lose any appreciable light transmission during normal use. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-38, 41 FR 55468, Dec. 20, 1976] Sec. 25.1387 Position light system dihedral angles. (a) Except as provided in paragraph (e) of this section, each forward and rear position light must, as installed, show unbroken light within the dihedral angles described in this section. (b) Dihedral angle L (left) is formed by two intersecting vertical planes, the first parallel to the longitudinal axis of the airplane, and the other at 110 degrees to the left of the first, as viewed when looking forward along the longitudinal axis. (c) Dihedral angle R (right) is formed by two intersecting vertical planes, the first parallel to the longitudinal axis of the airplane, and the other at 110 degrees to the right of the first, as viewed when looking forward along the longitudinal axis. (d) Dihedral angle A (aft) is formed by two intersecting vertical planes making angles of 70 degrees to the right and to the left, respectively, to a vertical plane passing through the longitudinal axis, as viewed when looking aft along the longitudinal axis. (e) If the rear position light, when mounted as far aft as practicable in accordance with Sec. 25.1385(c), cannot show unbroken light within dihedral angle A (as defined in paragraph (d) of this section), a solid angle or angles of obstructed visibility totaling not more than 0.04 steradians is allowable within that dihedral angle, if such solid angle is within a cone whose apex is at the rear position light and whose elements make an angle of 30 deg. with a vertical line passing through the rear position light. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-30, 36 FR 21278, Nov. 5, 1971] Sec. 25.1389 Position light distribution and intensities. (a) General. The intensities prescribed in this section must be provided by new equipment with light covers and color filters in place. Intensities must be determined with the light source operating at a steady value equal to the average luminous output of the source at the normal operating voltage of the airplane. The light distribution and intensity of each position light must meet the requirements of paragraph (b) of this section. (b) Forward and rear position lights. The light distribution and intensities of forward and rear position lights must be expressed in terms of minimum intensities in the horizontal plane, minimum intensities in any vertical plane, and maximum intensities in overlapping beams, within dihedral angles L, R, and A, and must meet the following requirements: (1) Intensities in the horizontal plane. Each intensity in the horizontal plane (the plane containing the longitudinal axis of the airplane and perpendicular to the plane of symmetry of the airplane) must equal or exceed the values in Sec. 25.1391. (2) Intensities in any vertical plane. Each intensity in any vertical plane (the plane perpendicular to the horizontal plane) must equal or exceed the appropriate value in Sec. 25.1393, where I is the minimum intensity prescribed in Sec. 25.1391 for the corresponding angles in the horizontal plane. (3) Intensities in overlaps between adjacent signals. No intensity in any overlap between adjacent signals may exceed the values given in Sec. 25.1395, except that higher intensities in overlaps may be used with main beam intensities substantially greater than the minima specified in Secs. 25.1391 and 25.1393 if the overlap intensities in relation to the main beam intensities do not adversely affect signal clarity. When the peak intensity of the forward position lights is more than 100 candles, the maximum overlap intensities between them may exceed the values given in Sec. 25.1395 if the overlap intensity in Area A is not more than 10 percent of peak position light intensity and the overlap intensity in Area B is not greater than 2.5 percent of peak position light intensity. Sec. 25.1391 Minimum intensities in the horizontal plane of forward and rear position lights. Each position light intensity must equal or exceed the applicable values in the following table:
Sec. 25.1393 Minimum intensities in any vertical plane of forward and rear position lights. Each position light intensity must equal or exceed the applicable values in the following table:
Sec. 25.1395 Maximum intensities in overlapping beams of forward and rear position lights. No position light intensity may exceed the applicable values in the following table, except as provided in Sec.25.1389(b)(3).
Where-- (a) Area A includes all directions in the adjacent dihedral angle that pass through the light source and intersect the common boundary plane at more than 10 degrees but less than 20 degrees; and (b) Area B includes all directions in the adjacent dihedral angle that pass through the light source and intersect the common boundary plane at more than 20 degrees. Sec. 25.1397 Color specifications. Each position light color must have the applicable International Commission on Illumination chromaticity coordinates as follows: (a) Aviation red-- "y" is not greater than 0.335; and "z" is not greater than 0.002. (b) Aviation green-- "x" is not greater than 0.440-0.320 y ; "x" is not greater than y --0.170; and "y" is not less than0.390-0.170 x. (c) Aviation white-- "x" is not less than0.300 and not greater than 0.540; "y" is not less than "x --0.040" or "y0--0.010", whichever is the smaller; and "y" is not greater than "x+0.020" nor "0.636-0.400 x"; Where "y0" is the "y" coordinate of the Planckian radiator for the value of "x" considered. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-27, 36 FR 12972, July 10, 1971] Sec. 25.1399 Riding light. (a) Each riding (anchor) light required for a seaplane or amphibian must be installed so that it can-- (1) Show a white light for at least 2 nautical miles at night under clear atmospheric conditions; and (2) Show the maximum unbroken light practicable when the airplane is moored or drifting on the water. (b) Externally hung lights may be used. Sec. 25.1401 Anticollision light system. (a) General. The airplane must have an anticollision light system that- (1) Consists of one or more approved anticollision lights located so that their light will not impair the crew's vision or detract from the conspicuity of the position lights; and (2) Meets the requirements of paragraphs (b) through (f) of this section. (b) Field of coverage. The system must consist of enough lights to illuminate the vital areas around the airplane considering the physical configuration and flight characteristics of the airplane. The field of coverage must extend in each direction within at least 75 degrees above and 75 degrees below the horizontal plane of the airplane, except that a solid angle or angles of obstructed visibility totaling not more than 0.03 steradians is allowable within a solid angle equal to 0.15 steradians centered about the longitudinal axis in the rearward direction. (c) Flashing characteristics. The arrangement of the system, that is, the number of light sources, beam width, speed of rotation, and other characteristics, must give an effective flash frequency of not less than 40, nor more than 100 cycles per minute. The effective flash frequency is the frequency at which the airplane's complete anticollision light system is observed from a distance, and applies to each sector of light including any overlaps that exist when the system consists of more than one light source. In overlaps, flash frequencies may exceed 100, but not 180 cycles per minute. (d) Color. Each anticollision light must be either aviation red or aviation white and must meet the applicable requirements of Sec. 25.1397. (e) Light intensity. The minimum light intensities in all vertical planes, measured with the red filter (if used) and expressed in terms of "effective" intensities, must meet the requirements of paragraph (f) of this section. The following relation must be assumed: [... equation goes here] where: Ie=effective intensity (candles). Normally, the maximum value of effective intensity is obtained when t2 and t1 are chosen so that the effective intensity is equal to the instantaneous intensity at t2 and t1. (f) Minimum effective intensities for anticollision lights. Each anticollision light effective intensity must equal or exceed the applicable values in the following table.
[Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-27, 36 FR 12972, July 10, 1971; Amdt. 25-41, 42 FR 36970, July 18, 1977] Sec. 25.1403 Wing icing detection lights. Unless operations at night in known or forecast icing conditions are prohibited by an operating limitation, a means must be provided for illuminating or otherwise determining the formation of ice on the parts of the wings that are critical from the standpoint of ice accumulation. Any illumination that is used must be of a type that will not cause glare or reflection that would handicap crewmembers in the performance of their duties. [Amdt. 25-38, 41 FR 55468, Dec. 20, 1976] |
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(a) Accessibility. Required safety equipment to be used by the crew in an emergency must be readily accessible. (b) Stowage provisions. Stowage provisions for required emergency equipment must be furnished and must-- (1) Be arranged so that the equipment is directly accessible and its location is obvious; and (2) Protect the safety equipment from inadvertent damage. (c) Emergency exit descent device. The stowage provisions for the emergency exit descent device required by Sec. 25.809(f) must be at the exits for which they are intended. (d) Liferafts. (1) The stowage provisions for the liferafts described in Sec. 25.1415 must accommodate enough rafts for the maximum number of occupants for which certification for ditching is requested. (2) Liferafts must be stowed near exits through which the rafts can be launched during an unplanned ditching. (3) Rafts automatically or remotely released outside the airplane must be attached to the airplane by means of the static line prescribed in Sec. 25.1415. (4) The stowage provisions for each portable liferaft must allow rapid detachment and removal of the raft for use at other than the intended exits. (e) Long-range signaling device. The stowage provisions for the long-range signaling device required by Sec. 25.1415 must be near an exit available during an unplanned ditching. (f) Life preserver stowage provisions. The stowage provisions for life preservers described in Sec. 25.1415 must accommodate one life preserver for each occupant for which certification for ditching is requested. Each life preserver must be within easy reach of each seated occupant. (g) Life line stowage provisions. If certification for ditching under Sec. 25.801 is requested, there must be provisions to store life lines. These provisions must-- (1) Allow one life line to be attached to each side of the fuselage; and (2) Be arranged to allow the life lines to be used to enable the occupants to stay on the wing after ditching. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-32, 37 FR 3972, Feb. 24, 1972; Amdt. 25-46, 43 FR 50598, Oct. 30, 1978; Amdt. 25-53, 45 FR 41593, June 19, 1980; Amdt. 25-70, 54 FR 43925, Oct. 27, 1989; Amdt. 25-79, 58 FR 45229, Aug. 26, 1993] Sec. 25.1413 [Removed. 55 FR 29785, July 20, 1990] EDITORIAL NOTE: For the convenience of the user, the removed text is set out below. Sec. 25.1413 Safety belts. (a) If there are means to indicate to the passengers when safety belts should be fastened, they must be installed to be operated from either pilot seat. (b) The rated strength of safety belts may not be less than that required to withstand the ultimate load factors specified in Sec. 25.561, considering the dimensional characteristics of the belt installation for the specific seat or berth arrangement. (c) Each belt and shoulder harness must be attached so that no part of the anchorage can fail at a load lower than that which would result from the application of ultimate load factors equal to those specified in Sec. 25.561, multiplied by a factor of 1.33. This factor must be used instead of the fitting factor prescribed in Sec. 25.625. The forward load factor need not be applied to safety belts for berths. (d) Each safety belt must be equipped with a metal to metal latching device. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-44, 43 FR 46233, Oct. 5, 1978; Amdt. 25-51, 45 FR 7755, Feb. 4, 1980] Sec. 25.1415 Ditching equipment. (a) Ditching equipment used in airplanes to be certificated for ditching under Sec. 25.801, and required by the operating rules of this chapter, must meet the requirements of this section. (b) Each liferaft and each life preserver must be approved. In addition- (1) Unless excess rafts of enough capacity are provided, the buoyancy and seating capacity beyond the rated capacity of the rafts must accommodate all occupants of the airplane in the event of a loss of one raft of the largest rated capacity; and (2) Each raft must have a trailing line, and must have a static line designed to hold the raft near the airplane but to release it if the airplane becomes totally submerged. (c) Approved survival equipment must be attached to each liferaft. (d) There must be an approved survival type emergency locator transmitter for use in one life raft. (e) For airplanes not certificated for ditching under Sec. 25.801 and not having approved life preservers, there must be an approved flotation means for each occupant. This means must be within easy reach of each seated occupant and must be readily removable from the airplane. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-29, 36 FR 18722, Sept. 21, 1971; Amdt 25-50, 45 FR 38348, June 9, 1980; Amdt. 25-72, 55 FR 29785, July 20, 1990; Amdt. 25-82, 59 FR 32057, June 21, 1994] Sec. 25.1416 [Removed. 55 FR 29785, July 20, 1985] EDITORIAL NOTE: For the convenience of the user, the removed text is set out below. Sec. 25.1416 Pneumatic de-icer boot system. If certification with ice protection provisions is desired and a pnuematic de-icer boot system is installed-- (a) The system must meet the requirements specified in Sec. 25.1419, (b) The system and its components must be designed to perform their intended function under any normal system operating temperature or pressure, and (c) Means to indicate to the flight crew that the pneumatic de-icer boot system is receiving adequate pressure and is functioning normally must be provided. [Amdt. 25-46, 43 FR 50598, Oct. 30, 1978] Sec. 25.1419 Ice protection. If certification with ice protection provisions is desired, the airplane must be able to safely operate in the continuous maximum and intermittent maximum icing conditions of appendix C. To establish that the airplane can operate within the continuous maximum and intermittent maximum conditions of appendix C: (a) An analysis must be performed to establish that the ice protection for the various components of the airplane is adequate, taking into account the various airplane operational configurations; and (b) To verify the ice protection analysis, to check for icing anomalies, and to demonstrate that the ice protection system and its components are effective, the airplane or its components must be flight tested in the various operational configurations, in measured natural atmospheric icing conditions and, as found necessary, by one or more of the following means: (1) Laboratory dry air or simulated icing tests, or a combination of both, of the components or models of the components. (2) Flight dry air tests of the ice protection system as a whole, or of its individual components. (3) Flight tests of the airplane or its components in measured simulated icing conditions. (c) Caution information, such as an amber caution light or equivalent, must be provided to alert the flightcrew when the anti-ice or de-ice system is not functioning normally. (d) For turbine engine powered airplanes, the ice protection provisions of this section are considered to be applicable primarily to the airframe. For the powerplant installation, certain additional provisions of subpart E of this part may be found applicable. [Doc. No. 24344, Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1421 Megaphones. If a megaphone is installed, a restraining means must be provided that is capable of restraining the megaphone when it is subjected to the ultimate inertia forces specified in Sec. 25.561(b)(3). [Amdt. 25-41, 42 FR 36970, July 18, 1977] |
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A public address system required by this chapter must-- (a) Be powerable when the aircraft is in flight or stopped on the ground, after the shutdown or failure of all engines and auxiliary power units, or the disconnection or failure of all power sources dependent on their continued operation, for-- (1) A time duration of at least 10 minutes, including an aggregate time duration of at least 5 minutes of announcements made by flight and cabin crewmembers, considering all other loads which may remain powered by the same source when all other power sources are inoperative; and (2) An additional time duration in its standby state appropriate or required for any other loads that are powered by the same source and that are essential to safety of flight or required during emergency conditions. (b) Be capable of operation within 10 seconds by a flight attendant at those stations in the passenger compartment from which the system is accessible. (c) Be intelligible at all passenger seats, lavatories, and flight attendant seats and work stations. (d) Be designed so that no unused, unstowed microphone will render the system inoperative. (e) Be capable of functioning independently of any required crewmember interphone system. (f) Be accessible for immediate use from each of two flight crewmember stations in the pilot compartment. (g) For each required floor-level passenger emergency exit which has an adjacent flight attendant seat, have a microphone which is readily accessible to the seated flight attendant, except that one microphone may serve more than one exit, provided the proximity of the exits allows unassisted verbal communication between seated flight attendants. [Amdt. 25-79, 58 FR 45229, Aug. 26, 1993] Sec. 25.1431 Electronic equipment. (a) In showing compliance with Sec. 25.1309 (a) and (b) with respect to radio and electronic equipment and their installations, critical environmental conditions must be considered. (b) Radio and electronic equipment must be supplied with power under the requirements of Sec. 25.1355(c). (c) Radio and electronic equipment, controls, and wiring must be installed so that operation of any one unit or system of units will not adversely affect the simultaneous operation of any other radio or electronic unit, or system of units, required by this chapter. Sec. 25.1433 Vacuum systems. There must be means, in addition to the normal pressure relief, to automatically relieve the pressure in the discharge lines from the vacuum air pump when the delivery temperature of the air becomes unsafe. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-72, 55 FR 29785, July 20, 1990] Sec. 25.1435 Hydraulic systems. (a) Design. (1) Each element of the hydraulic system must be designed to withstand, without deformation that would prevent it from performing its intended function, the design operating pressure loads in combination with limit structural loads which may be imposed. (2) Each element of the hydraulic system must be able to withstand, without rupture, the design operating pressure loads multiplied by a factor of 1.5 in combination with ultimate structural loads that can reasonably occur simultaneously. Design operating pressure is maximum normal operating pressure, excluding transient pressure. (b) Tests and analysis. (1) A complete hydraulic system must be static tested to show that it can withstand 1.5 times the design operating pressure without a deformation of any part of the system that would prevent it from performing its intended function. Clearance between structural members and hydraulic system elements must be adequate and there must be no permanent detrimental deformation. For the purpose of this test, the pressure relief valve may be made inoperable to permit application of the required pressure. (2) Compliance with Sec. 25.1309 for hydraulic systems must be shown by functional tests, endurance tests, and analyses. The entire system, or appropriate subsystems, must be tested in an airplane or in a mock-up installation to determine proper performance and proper relation to other aircraft systems. The functional tests must include simulation of hydraulic system failure conditions. Endurance tests must simulate the repeated complete flights that could be expected to occur in service. Elements which fail during the tests must be modified in order to have the design deficiency corrected and, where necessary, must be sufficiently retested. Simulation of operating and environmental conditions must be completed on elements and appropriate portions of the hydraulic system to the extent necessary to evaluate the environmental effects. Compliance with Sec. 25.1309 must take into account the following: (i) Static and dynamic loads including flight, ground, pilot, hydrostatic, inertial and thermally induced loads, and combinations thereof. (ii) Motion, vibration, pressure transients, and fatigue. (iii) Abrasion, corrosion, and erosion. (iv) Fluid and material compatibility. (v) Leakage and wear. (c) Fire protection. Each hydraulic system using flammable hydraulic fluid must meet the applicable requirements of Secs. 25.863, 25.1183, 25.1185, and 25.1189. [Amdt. 25-13, 32 FR 9154, June 28, 1967, as amended by Amdt. 25-41, 42 FR 36971, July 18, 1977; Amdt. 25-72, 55 FR 29786, July 20, 1990] Sec. 25.1438 Pressurization and pneumatic systems. (a) Pressurization system elements must be burst pressure tested to 2.0 times, and proof pressure tested to 1.5 times, the maximum normal operating pressure. (b) Pneumatic system elements must be burst pressure tested to 3.0 times, and proof pressure tested to 1.5 times, the maximum normal operating pressure. (c) An analysis, or a combination of analysis and test, may be substituted for any test required by paragraph (a) or (b) of this section if the Administrator finds it equivalent to the required test. [Amdt. 25-41, 42 FR 36971, July 18, 1977] Sec. 25.1439 Protective breathing equipment. (a) If there is a class A, B, or E cargo compartment, protective breathing equipment must be installed for the use of appropriate crewmembers. In addition, protective breathing equipment must be installed in each isolated separate compartment in the airplane, including upper and lower lobe galleys, in which crewmember occupancy is permitted during flight for the maximum number of crewmembers expected to be in the area during any operation. (b) For protective breathing equipment required by paragraph (a) of this section or by any operating rule of this chapter, the following apply: (1) The equipment must be designed to protect the flight crew from smoke, carbon dioxide, and other harmful gases while on flight deck duty and while combating fires in cargo compartments. (2) The equipment must include-- (i) Masks covering the eyes, nose, and mouth; or (ii) Masks covering the nose and mouth, plus accessory equipment to cover the eyes. (3) The equipment, while in use, must allow the flight crew to use the radio equipment and to communicate with each other, while at their assigned duty stations. (4) The part of the equipment protecting the eyes may not cause any appreciable adverse effect on vision and must allow corrective glasses to be worn. (5) The equipment must supply protective oxygen of 15 minutes duration per crewmember at a pressure altitude of 8,000 feet with a respiratory minute volume of 30 liters per minute BTPD. If a demand oxygen system is used, a supply of 300 liters of free oxygen at 70 deg. F. and 760 mm. Hg. pressure is considered to be of 15-minute duration at the prescribed altitude and minute volume. If a continuous flow protective breathing system is used (including a mask with a standard rebreather bag) a flow rate of 60 liters per minute at 8,000 feet (45 liters per minute at sea level) and a supply of 600 liters of free oxygen at 70 deg. F. and 760 mm. Hg. pressure is considered to be of 15 minute duration at the prescribed altitude and minute volume. BTPD refers to body temperature conditions (that is, 37 deg. C., at ambient pressure, dry). (6) The equipment must meet the requirements of paragraphs (b) and (c) of Sec. 25.1441. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-38, 41 FR 55468, Dec. 20, 1976] Sec. 25.1441 Oxygen equipment and supply. (a) If certification with supplemental oxygen equipment is requested, the equipment must meet the requirements of this section and Secs. 25.1443 through 25.1453. (b) The oxygen system must be free from hazards in itself, in its method of operation, and in its effect upon other components. (c) There must be a means to allow the crew to readily determine, during flight, the quantity of oxygen available in each source of supply. (d) The oxygen flow rate and the oxygen equipment for airplanes for which certification for operation above 40,000 feet is requested must be approved. Sec. 25.1443 Minimum mass flow of supplemental oxygen. (a) If continuous flow equipment is installed for use by flight crewmembers, the minimum mass flow of supplemental oxygen required for each crewmember may not be less than the flow required to maintain, during inspiration, a mean tracheal oxygen partial pressure of 149 mm. Hg. when breathing 15 liters per minute, BTPS, and with a maximum tidal volume of 700 cc. with a constant time interval between respirations. (b) If demand equipment is installed for use by flight crewmembers, the minimum mass flow of supplemental oxygen required for each crewmember may not be less than the flow required to maintain, during inspiration, a mean tracheal oxygen partial pressure of 122 mm. Hg., up to and including a cabin pressure altitude of 35,000 feet, and 95 percent oxygen between cabin pressure altitudes of 35,000 and 40,000 feet, when breathing 20 liters per minute BTPS. In addition, there must be means to allow the crew to use undiluted oxygen at their discretion. (c) For passengers and cabin attendants, the minimum mass flow of supplemental oxygen required for each person at various cabin pressure altitudes may not be less than the flow required to maintain, during inspiration and while using the oxygen equipment (including masks) provided, the following mean tracheal oxygen partial pressures: (1) At cabin pressure altitudes above 10,000 feet up to and including 18,500 feet, a mean tracheal oxygen partial pressure of 100 mm. Hg. when breathing 15 liters per minute, BTPS, and with a tidal volume of 700 cc. with aconstant time interval between respirations. (2) At cabin pressure altitudes above 18,500 feet up to and including 40,000 feet, a mean tracheal oxygen partial pressure of 83.8 mm. Hg. when breathing 30 liters per minute, BTPS, and with a tidal volume of 1,100 cc. with a constant time interval between respirations. (d) If first-aid oxygen equipment is installed, the minimum mass flow of oxygen to each user may not be less than four liters per minute, STPD. However, there may be a means to decrease this flow to not less than two liters per minute, STPD, at any cabin altitude. The quantity of oxygen required is based upon an average flow rate of three liters per minute per person for whom first-aid oxygen is required. (e) If portable oxygen equipment is installed for use by crewmembers, the minimum mass flow of supplemental oxygen is the same as specified in paragraph (a) or (b) of this section, whichever is applicable. Sec. 25.1445 Equipment standards for the oxygen distributing system. (a) When oxygen is supplied to both crew and passengers, the distribution system must be designed for either-- (1) A source of supply for the flight crew on duty and a separate source for the passengers and other crewmembers; or (2) A common source of supply with means to separately reserve the minimum supply required by the flight crew on duty. (b) Portable walk-around oxygen units of the continuous flow, diluter demand, and straight demand kinds may be used to meet the crew or passenger breathing requirements. Sec. 25.1447 Equipment standards for oxygen dispensing units. If oxygen dispensing units are installed, the following apply: (a) There must be an individual dispensing unit for each occupant for whom supplemental oxygen is to be supplied. Units must be designed to cover the nose and mouth and must be equipped with a suitable means to retain the unit in position on the face. Flight crew masks for supplemental oxygen must have provisions for the use of communication equipment. (b) If certification for operation up to and including 25,000 feet is requested, an oxygen supply terminal and unit of oxygen dispensing equipment for the immediate use of oxygen by each crewmember must be within easy reach of that crewmember. For any other occupants, the supply terminals and dispensing equipment must be located to allow the use of oxygen as required by the operating rules in this chapter. (c) If certification for operation above 25,000 feet is requested, there must be oxygen dispensing equipment meeting the following requirements: (1) There must be an oxygen dispensing unit connected to oxygen supply terminals immediately available to each occupant, wherever seated, and at least two oxygen dispensing units connected to oxygen terminals in each lavatory. The total number of dispensing units and outlets in the cabin must exceed the number of seats by at least 10 percent. The extra units must be as uniformly distributed throughout the cabin as practicable. If certification for operation above 30,000 feet is requested, the dispensing units providing the required oxygen flow must be automatically presented to the occupants before the cabin pressure altitude exceeds 15,000 feet. The crew must be provided with a manual means of making the dispensing units immediately available in the event of failure of the automatic system. (2) Each flight crewmember on flight deck duty must be provided with a quick-donning type oxygen dispensing unit connected to an oxygen supply terminal. This dispensing unit must be immediately available to the flight crewmember when seated at his station, and installed so that it: (i) Can be placed on the face from its ready position, properly secured, sealed, and supplying oxygen upon demand, with one hand, within five seconds and without disturbing eyeglasses or causing delay in proceeding with emergency duties; and (ii) Allows, while in place, the performance of normal communication functions. (3) The oxygen dispensing equipment for the flight crewmembers must be: (i) The diluter demand or pressure demand (pressure demand mask with a diluter demand pressure breathing regulator) type, or other approved oxygen equipment shown to provide the same degree of protection, for airplanes to be operated above 25,000 feet. (ii) The pressure demand (pressure demand mask with a diluter demand pressure breathing regulator) type with mask-mounted regulator, or other approved oxygen equipment shown to provide the same degree of protection, for airplanes operated at altitudes where decompressions that are not extremely improbable may expose the flightcrew to cabin pressure altitudes in excess of 34,000 feet. (4) Portable oxygen equipment must be immediately available for each cabin attendant. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-41, 42 FR 36971, July 18, 1977; Amdt. 25-87, 61 FR 28696, June 5, 1996] Sec. 25.1449 Means for determining use of oxygen. There must be a means to allow the crew to determine whether oxygen is being delivered to the dispensing equipment. Sec. 25.1450 Chemical oxygen generators. (a) For the purpose of this section, a chemical oxygen generator is defined as a device which produces oxygen by chemical reaction. (b) Each chemical oxygen generator must be designed and installed in accordance with the following requirements: (1) Surface temperature developed by the generator during operation may not create a hazard to the airplane or to its occupants. (2) Means must be provided to relieve any internal pressure that may be hazardous. (c) In addition to meeting the requirements in paragraph (b) of this section, each portable chemical oxygen generator that is capable of sustained operation by successive replacement of a generator element must be placarded to show-- (1) The rate of oxygen flow, in liters per minute; (2) The duration of oxygen flow, in minutes, for the replaceable generator element; and (3) A warning that the replaceable generator element may be hot, unless the element construction is such that the surface temperature cannot exceed 100 degrees F. [Amdt. 25-41, 42 FR 36971, July 18, 1977] Sec. 25.1451 [Removed. 55 FR 29786, July 20, 1990] EDITORIAL NOTE: For the convenience of the user, the removed text is set out below. Sec. 25.1451 Fire protection for oxygen equipment. (a) Oxygen equipment and lines may not be in any designated fire zone. (b) Oxygen equipment and lines must be protected from heat that may be generated in, or escape from, any designated fire zone. (c) Oxygen equipment and lines must be installed so that escaping oxygen cannot cause ignition of grease, fluid, or vapor accumulations that are present in normal operation or as a result of failure or malfunction of any system. Sec. 25.1453 Protection of oxygen equipment from rupture. Oxygen pressure tanks, and lines between tanks and the shutoff means, must be-- (a) Protected from unsafe temperatures; and (b) Located where the probability and hazards of rupture in a crash landing are minimized. Sec. 25.1455 Draining of fluids subject to freezing. If fluids subject to freezing may be drained overboard in flight or during ground operation, the drains must be designed and located to prevent the formation of hazardous quantities of ice on the airplane as a result of the drainage. [Amdt. 25-23, 35 FR 5680, Apr. 8, 1970] Sec. 25.1457 Cockpit voice recorders. (a) Each cockpit voice recorder required by the operating rules of this chapter must be approved and must be installed so that it will record the following: (1) Voice communications transmitted from or received in the airplane by radio. (2) Voice communications of flight crewmembers on the flight deck. (3) Voice communications of flight crewmembers on the flight deck, using the airplane's interphone system. (4) Voice or audio signals identifying navigation or approach aids introduced into a headset or speaker. (5) Voice communications of flight crewmembers using the passenger loudspeaker system, if there is such a system and if the fourth channel is available in accordance with the requirements of paragraph (c)(4)(ii) of this section. (b) The recording requirements of paragraph (a)(2) of this section must be met by installing a cockpit-mounted area microphone, located in the best position for recording voice communications originating at the first and second pilot stations and voice communications of other crewmembers on the flight deck when directed to those stations. The microphone must be so located and, if necessary, the preamplifiers and filters of the recorder must be so adjusted or supplemented, that the intelligibility of the recorded communications is as high as practicable when recorded under flight cockpit noise conditions and played back. Repeated aural or visual playback of the record may be used in evaluating intelligibility. (c) Each cockpit voice recorder must be installed so that the part of the communication or audio signals specified in paragraph (a) of this section obtained from each of the following sources is recorded on a separate channel: (1) For the first channel, from each boom, mask, or hand-held microphone, headset, or speaker used at the first pilot station. (2) For the second channel from each boom, mask, or hand-held microphone, headset, or speaker used at the second pilot station. (3) For the third channel--from the cockpit-mounted area microphone. (4) For the fourth channel, from-- (i) Each boom, mask, or hand-held microphone, headset, or speaker used at the station for the third and fourth crew members; or (ii) If the stations specified in paragraph (c)(4)(i) of this section are not required or if the signal at such a station is picked up by another channel, each microphone on the flight deck that is used with the passenger loudspeaker system, if its signals are not picked up by another channel. (5) As far as is practicable all sounds received by the microphone listed in paragraphs (c) (1), (2), and (4) of this section must be recorded without interruption irrespective of the position of the interphone-transmitter key switch. The design shall ensure that sidetone for the flight crew is produced only when the interphone, public address system, or radio transmitters are in use. (d) Each cockpit voice recorder must be installed so that-- (1) It receives its electric power from the bus that provides the maximum reliability for operation of the cockpit voice recorder without jeopardizing service to essential or emergency loads; (2) There is an automatic means to simultaneously stop the recorder and prevent each erasure feature from functioning, within 10 minutes after crash impact; and (3) There is an aural or visual means for preflight checking of the recorder for proper operation. (e) The record container must be located and mounted to minimize the probability of rupture of the container as a result of crash impact and consequent heat damage to the record from fire. In meeting this requirement, the record container must be as far aft as practicable, but may not be where aft mounted engines may crush the container during impact. However, it need not be outside of the pressurized compartment. (f) If the cockpit voice recorder has a bulk erasure device, the installation must be designed to minimize the probability of inadvertent operation and actuation of the device during crash impact. (g) Each recorder container must-- (1) Be either bright orange or bright yellow; (2) Have reflective tape affixed to its external surface to facilitate its location under water; and (3) Have an underwater locating device, when required by the operating rules of this chapter, on or adjacent to the container which is secured in such manner that they are not likely to be separated during crash impact. [Doc. No. 5066, 29 FR 18291, Dec. 24, 1964, as amended by Amdt. 25-2, 30 FR 3932, Mar. 26, 1965; Amdt. 25-16, 32 FR 13914, Oct. 6, 1967; Amdt. 25-41, 42 FR 36971, July 18, 1977; Amdt. 25-65, 53 FR 26143, July 11, 1988] Sec. 25.1459 Flight recorders. (a) Each flight recorder required by the operating rules of this chapter must be installed so that-- (1) It is supplied with airspeed, altitude, and directional data obtained from sources that meet the accuracy requirements of Secs. 25.1323, 25.1325, and 25.1327, as appropriate; (2) The vertical acceleration sensor is rigidly attached, and located longitudinally either within the approved center of gravity limits of the airplane, or at a distance forward or aft of these limits that does not exceed 25 percent of the airplane's mean aerodynamic chord; (3) It receives its electrical power from the bus that provides the maximum reliability for operation of the flight recorder without jeopardizing service to essential or emergency loads; (4) There is an aural or visual means for preflight checking of the recorder for proper recording of data in the storage medium. (5) Except for recorders powered solely by the engine-driven electrical generator system, there is an automatic means to simultaneously stop a recorder that has a data erasure feature and prevent each erasure feature from functioning, within 10 minutes after crash impact; and (6) There is a means to record data from which the time of each radio transmission either to or from ATC can be determined. (b) Each nonejectable record container must be located and mounted so as to minimize the probability of container rupture resulting from crash impact and subsequent damage to the record from fire. In meeting this requirement the record container must be located as far aft as practicable, but need not be aft of the pressurized compartment, and may not be where aft-mounted engines may crush the container upon impact. (c) A correlation must be established between the flight recorder readings of airspeed, altitude, and heading and the corresponding readings (taking into account correction factors) of the first pilot's instruments. The correlation must cover the airspeed range over which the airplane is to be operated, the range of altitude to which the airplane is limited, and 360 degrees of heading. Correlation may be established on the ground as appropriate. (d) Each recorder container must-- (1) Be either bright orange or bright yellow; (2) Have reflective tape affixed to its external surface to facilitate its location under water; and (3) Have an underwater locating device, when required by the operating rules of this chapter, on or adjacent to the container which is secured in such a manner that they are not likely to be separated during crash impact. (e) Any novel or unique design or operational characteristics of the aircraft shall be evaluated to determine if any dedicated parameters must be recorded on flight recorders in addition to or in place of existing requirements. [Amdt. 25-8, 31 FR 127, Jan. 6, 1966, as amended by Amdt. 25-25, 35 FR 13192, Aug. 19, 1970; Amdt. 25-37, 40 FR 2577, Jan. 14, 1975; Amdt. 25-41, 42 FR 36971, July 18, 1977; Amdt. 25-65, 53 FR 26144, July 11, 1988] Sec. 25.1461 Equipment containing high energy rotors. (a) Equipment containing high energy rotors must meet paragraph (b), (c), or (d) of this section. (b) High energy rotors contained in equipment must be able to withstand damage caused by malfunctions, vibration, abnormal speeds, and abnormal temperatures. In addition-- (1) Auxiliary rotor cases must be able to contain damage caused by the failure of high energy rotor blades; and (2) Equipment control devices, systems, and instrumentation must reasonably ensure that no operating limitations affecting the integrity of high energy rotors will be exceeded in service. (c) It must be shown by test that equipment containing high energy rotors can contain any failure of a high energy rotor that occurs at the highest speed obtainable with the normal speed control devices inoperative. (d) Equipment containing high energy rotors must be located where rotor failure will neither endanger the occupants nor adversely affect continued safe flight. [Amdt. 25-41, 42 FR 36971, July 18, 1977] |
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