24800-ZW4-H03 BOX ASSY., REMOTE CONTROL (Honda Code 8834251). Honda
BF25D6 LRGA, BF25D6 SRGA, BF25DK0 LRGA, BF30D4 LRGA, BF30D5 LRGA, BF30DK0 LRGA, BF40A6 LHA, BF40AK0 LHA
BOX
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Honda entire parts catalog list:
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
- REMOTE CONTROL (1) » 24800-ZW4-H03
Information:
Power
P = IEwhere P = power in wattsI = current in amperesE = voltage in voltsThis equation for power may also be transposed to: From Ohm's law it is known that E = IR. If this expression for voltage is substituted in the power law, we can derive the additional equation: P = I2RIf we use the equation for current from Ohm's law, I = E/R, the equation for power becomes: *See "Ugly's Electrical Reference" (SEBD0983) for additional information.Resistance
Series Circuits RT = R1 + R2 + R3 + ... RN where RN = resistance in the individual resistorsRT = total resistance in circuitReactance
XL = 2 π f Lwhere XL = inductive reactance in ohms f = frequency in hertzL = inductance in henriesπ = 3.1416 where XC = capacitive reactance in ohms f = frequency in hertzC = capacitance in faradsπ = 3.1416Impedance
where Z = impedance in ohms R = resistance in ohmsXL = inductive reactance in ohmsXC = capacitive reactance in ohmsNote that the impendance will vary with frequency, since both XC and XL are frequency dependent. In practical AC power circuits, XC is often small and can be neglected. In that case, the formula above simplifies to: Transformer Voltage Conversion
where VS = secondary voltage VP = primary voltageNS = number of secondary turnsNP = number of primary turnsPower Factor
In mathematical terms, the power factor is equal to the cosine of the angle by which the current leads or lags the voltage. If the current lags the voltage in an inductive circuit by 60 degrees, the power factor will be 0.5, the value of the cosine function at 60 degrees. If the phase of the current in a load leads the phase of the voltage, the load is said to have a leading power factor; if it lags, a lagging power factor. If the voltage and current are in phase, the circuit has a unity power factor.Equation Summary Diagram
Three Phase Connection Systems:
Electrical Enclosure Protection = IEC
The degrees of protection provided within an electrical enclosure is expressed in terms of the letters IP followed by two numerals. Mechanical protection against impact damage is defined by an optional third numeral. Example: An IP55 enclosure protects its contents against dust and spray from water jets.Reference: DIN 40050 of July 1980, IEC 144 of 1963, IEC 529 of 1976, NF C 20-010 of April 1977Electrical Enclosure Protection - NEMA
Electrical Tables
Table 1 Electrical Formulae Table 2 KV A of AC Circuits Table 3 Copper Wire Characteristics Table 4 Single-Phase AC Motors Full Load Currents in Amperes Table 5 Three-Phase AC Motors - 80% Power Factor Full Load Current in Amperes - Induction-Type, Squirrel Cage and Wound Rotor Table 6 Direct Current Motors Full Load Current in Amperes Table 7 Conduit Sizes for Conductors Table 8 Allowable Current-Carrying Capacities of Insulated Copper Conductors Table 9 Code Letters Usually Applied to Ratings of Motors Normally Started on Full Voltage Table 10 Identifying Code Letters on AC Motors Table 11 Conversion - Heat and Energy Table 12 Approximate Efficiencies - Squirrel Cage Induction Motor Table 13 - Approximate Electric Motor Efficiency to Use in Calculating Input Table 14 Reduced Voltage Starters
P = IEwhere P = power in wattsI = current in amperesE = voltage in voltsThis equation for power may also be transposed to: From Ohm's law it is known that E = IR. If this expression for voltage is substituted in the power law, we can derive the additional equation: P = I2RIf we use the equation for current from Ohm's law, I = E/R, the equation for power becomes: *See "Ugly's Electrical Reference" (SEBD0983) for additional information.Resistance
Series Circuits RT = R1 + R2 + R3 + ... RN where RN = resistance in the individual resistorsRT = total resistance in circuitReactance
XL = 2 π f Lwhere XL = inductive reactance in ohms f = frequency in hertzL = inductance in henriesπ = 3.1416 where XC = capacitive reactance in ohms f = frequency in hertzC = capacitance in faradsπ = 3.1416Impedance
where Z = impedance in ohms R = resistance in ohmsXL = inductive reactance in ohmsXC = capacitive reactance in ohmsNote that the impendance will vary with frequency, since both XC and XL are frequency dependent. In practical AC power circuits, XC is often small and can be neglected. In that case, the formula above simplifies to: Transformer Voltage Conversion
where VS = secondary voltage VP = primary voltageNS = number of secondary turnsNP = number of primary turnsPower Factor
In mathematical terms, the power factor is equal to the cosine of the angle by which the current leads or lags the voltage. If the current lags the voltage in an inductive circuit by 60 degrees, the power factor will be 0.5, the value of the cosine function at 60 degrees. If the phase of the current in a load leads the phase of the voltage, the load is said to have a leading power factor; if it lags, a lagging power factor. If the voltage and current are in phase, the circuit has a unity power factor.Equation Summary Diagram
Three Phase Connection Systems:
Electrical Enclosure Protection = IEC
The degrees of protection provided within an electrical enclosure is expressed in terms of the letters IP followed by two numerals. Mechanical protection against impact damage is defined by an optional third numeral. Example: An IP55 enclosure protects its contents against dust and spray from water jets.Reference: DIN 40050 of July 1980, IEC 144 of 1963, IEC 529 of 1976, NF C 20-010 of April 1977Electrical Enclosure Protection - NEMA
Electrical Tables
Table 1 Electrical Formulae Table 2 KV A of AC Circuits Table 3 Copper Wire Characteristics Table 4 Single-Phase AC Motors Full Load Currents in Amperes Table 5 Three-Phase AC Motors - 80% Power Factor Full Load Current in Amperes - Induction-Type, Squirrel Cage and Wound Rotor Table 6 Direct Current Motors Full Load Current in Amperes Table 7 Conduit Sizes for Conductors Table 8 Allowable Current-Carrying Capacities of Insulated Copper Conductors Table 9 Code Letters Usually Applied to Ratings of Motors Normally Started on Full Voltage Table 10 Identifying Code Letters on AC Motors Table 11 Conversion - Heat and Energy Table 12 Approximate Efficiencies - Squirrel Cage Induction Motor Table 13 - Approximate Electric Motor Efficiency to Use in Calculating Input Table 14 Reduced Voltage Starters
Parts box Honda:
06240-ZW7-U10
06240-ZW7-U10 BOX KIT, L. REMOTE CONTROL (Honda Code 6796171). (FLUSH MOUNT)
BF115A1 LA, BF115A1 LCA, BF115A1 XA, BF115A1 XCA, BF115A2 LA, BF115A2 LCA, BF115A2 XA, BF115A2 XCA, BF115A3 LA, BF115A3 LCA, BF115A3 XA, BF115A3 XCA, BF115A4 LA, BF115A4 LCA, BF115A4 XA, BF115A4 XCA, BF115A5 LA, BF115A5 LCA, BF115A5 XA, BF115A5 XCA,
06240-ZW5-U70
06240-ZW5-U70 BOX KIT, L. REMOTE CONTROL (Honda Code 6796155). (TOP MOUNT DUAL)
BF115A1 LA, BF115A1 LCA, BF115A1 XA, BF115A1 XCA, BF115A2 LA, BF115A2 LCA, BF115A2 XA, BF115A2 XCA, BF115A3 LA, BF115A3 LCA, BF115A3 XA, BF115A3 XCA, BF115A4 LA, BF115A4 LCA, BF115A4 XA, BF115A4 XCA, BF115A5 LA, BF115A5 LCA, BF115A5 XA, BF115A5 XCA,
24800-ZW4-H01
24800-ZW4-H01 BOX ASSY., REMOTE CONTROL (Honda Code 7702335). (A/T)
BF25D4 LRGA, BF25D4 SRGA, BF25D5 LRGA, BF25D5 SRGA, BF25D6 LRGA, BF25D6 SRGA, BF25DK0 LRGA, BF30D4 LRGA, BF30D5 LRGA, BF30D6 LRGA, BF30DK0 LRGA, BF40A4 LHA, BF40A5 LHA, BF40A6 LHA, BF40AK0 LHA
24800-ZW4-H00
24800-ZW4-H00 BOX ASSY., REMOTE CONTROL (Honda Code 7531478). (A/T)
BF25D4 LRGA, BF25D4 SRGA, BF25D5 LRGA, BF25D5 SRGA, BF30D4 LRGA, BF30D6 LRGA, BF40A4 LHA, BF40A5 LHA
24800-ZW4-H02
24800-ZW4-H02 BOX ASSY., REMOTE CONTROL (Honda Code 8609281). (A/T)
BF25DK0 LRGA, BF30D4 LRGA, BF30D5 LRGA, BF30DK0 LRGA, BF40AK0 LHA