Strengthening　low-chromium　iron-based　alloys　with　multiple　alloy　elements　is　a　crucial　strategy　for　developing　＂casing-friendly＂　hardbanding　materials.　In　this　paper,　four　kinds　of　low-chromium　iron-based　hardfacing　alloys　with　different　Ti　contents　were　prepared　by　flux-cored　arc　welding　technology,　and　the　effect　of　Ti　content　on　the　microstructure,　hardness,　and　wear　performance　under　the　abrasive　wear　and　dry　sliding　wear　was　analyzed.　The　in　situ　TiC-reinforced　iron-based　hardfacing　alloys　exhibited　microstructure　comprising　austenite,　martensite,　carbides,　and　in　situ　TiC　particles.　The　in　situ　formation　of　TiC　particles　consumed　the　carbon　in　the　alloy　and　thus　raised　the　martensite　start　temperature,　resulting　in　a　reduction　in　the　mass　fraction　of　austenite　and　an　increase　in　the　martensite.　Among　the　four　hardfacing　alloys,　the　alloy　with　5　wt.%　Ti　exhibited　the　highest　hardness　(836.3　HV0.2)　and　the　best　wear　resistance　due　to　its　highest　martensite　mass　fraction　(69.97　wt.%).　The　matrix　with　in　situ　TiC　particles　and　martensite　effectively　resisted　the　cutting　of　abrasive　grains　and　the　wear　mechanism　developed　from　the　microplowing　in　0Ti　alloy　to　microcutting　in　in　situ　TiC-reinforced　iron-based　hardfacing　alloys　in　abrasive　wear　tests.　In　dry　sliding　wear　tests,　TiC　particles　were　released　and　slid　on　the　surface　of　the　alloys,　resulting　in　the　formation　of　grooves,　while　the　formation　of　the　tribochemical　reaction　layers　contributed　to　a　reduction　in　the　friction　coefficient　and　wear　rate.　This　study　provides　a　theoretical　foundation　for　the　development　of　＂casing-friendly＂　hardbanding　materials.