On February 7, 2021, about 1615 eastern standard time, a Taylorcraft BC-65, N24476, was substantially damaged when it was involved in an accident near Columbia, South Carolina. The pilot sustained minor injuries. The airplane was operating as a Title 14 Code of Federal Regulations Part 91 personal flight.

The student pilot, who was the owner of the airplane, stated he departed Columbia Airport (CUB), Columbia, South Carolina, about 1605 and was in cruise flight at an altitude of 2,000 ft mean seal level (msl) when the engine began to lose power “as if something was blocking fuel from getting to the engine.” The student pilot reported that he applied carburetor heat “which was no help and only made for a greater loss of much needed rpms.” When interviewed, the student pilot explained that he applied full carburetor heat but turned it back off about 30 seconds later when there was no improvement to the loss of engine rpm. The student pilot said the engine eventually stopped producing power, and he made a forced landing to a road located in a subdivision that was under construction. The airplane sustained substantial damage to the left wing when it collided with construction equipment during the landing roll.

A postaccident examination of the engine revealed that when the engine was manually rotated, spark was produced to each ignition lead, and compression and valve train continuity were established on all four cylinders; however, compression was lower on the No. 1 cylinder than the other cylinders. The spark plugs exhibited normal wear with some black soot on the electrodes. The engine was approved to use auto fuel, which was observed in both fuel tanks. Examination of the fuel system revealed the fuel lines to the carburetor were clear. The air filter was also clean. Examination of the airframe and engine revealed no mechanical malfunctions or anomalies that would have precluded normal operation.

At 1553, the weather reported at CUB, about 9.5 nautical miles northeast of the accident site, included a temperature of 55°F and a dew point of 36°F. The calculated relative humidity at this temperature and dewpoint was about 48%.

A high-resolution rapid refresh (HRRR) model sounding was created for the accident time and location with a surface elevation of 335 ft mean sea level (msl). At 1,752 ft msl, the HRRR sounding indicated a temperature of about 44°F, a dew point of about 33°F, and a relative humidity of 66%. At 2,351 ft msl, the HRRR sounding indicated a temperature of about 41°F, a dew point of about 33°F, and a relative humidity of 72%. Review of the icing probability chart contained within Federal Aviation Administration (FAA) Special Airworthiness Information Bulletin (SAIB) CE-09-35 revealed the atmospheric conditions at those altitudes at the time of the accident were conducive to “serious icing at cruise power.”

According to FAA Advisory Circular 20-113, "to prevent accidents due to induction system icing, the pilot should regularly use [carburetor] heat under conditions known to be conducive to atmospheric icing and be alert at all times for indications of icing in the fuel system." The circular recommended that when operating in conditions where the relative humidity is greater than 50% and the temperature is below 70°F, the pilot should "apply carburetor heat briefly immediately before takeoff, particularly with float type carburetors, to remove any ice which may have been accumulated during taxi and runup." It also stated, "Remain alert for indications of induction system icing during takeoff and climb-out, especially when the relative humidity is above 50 percent, or when visible moisture is present in the atmosphere."