Definition and Factors Affecting Ampacity
– Ampacity is a portmanteau for ampere capacity.
– It is defined as the maximum current, in amperes, that a conductor can carry continuously without exceeding its temperature rating.
– It is also known as current-carrying capacity.
– Factors affecting ampacity include the conductor’s ability to dissipate heat without damage, insulation temperature rating, electrical resistance of the conductor material, ambient temperature, and the ability of the insulated conductor to dissipate heat to the surroundings.
Conductors and Heat Dissipation
– All common electrical conductors have resistance to the flow of electricity.
– Copper or aluminum conductors can carry a large amount of current without damage.
– Insulation is typically damaged by heat before conductor damage occurs.
– The overall surface area of a conductor and the environment’s ability to absorb heat impact heat dissipation.
Derating and Installation Regulations
– Installation regulations specify that the most severe condition along the cable run governs each cable conductor’s rating.
– Wet or oily locations may require lower temperature ratings for cables.
– Derating is necessary for multiple cables in proximity as they contribute heat to each other.
– The overall ampacity of insulated cable conductors in a bundle of more than three cables must be derated.
– Wiring regulations usually provide derating factors.
Temperature Ratings and Current Limits
– The maximum allowable temperatures at the surface of the conductor vary based on the type of insulating material.
– Ambient air temperature is considered when determining temperature ratings.
– Conductor ampacity may need to be decreased (derated) when conductors are in a grouping, enclosed in conduit, or an enclosure restricting heat dissipation.
– Ampacity ratings are normally for continuous current, but short periods of overcurrent are usually tolerated.
– The design of an electrical system takes into account the current-carrying capacity of all conductors.
N/A Source: https://en.wikipedia.org/wiki/Ampacity
This article relies largely or entirely on a single source. (April 2023) |
Ampacity is a portmanteau for ampere capacity defined by National Electrical Codes, in some North American countries. Ampacity is defined as the maximum current, in amperes, that a conductor can carry continuously under the conditions of use without exceeding its temperature rating. Also described as current-carrying capacity.
According to the International Electrotechnical Commission, the current-carrying capacity (ampacity, US) is the "maximum value of electric current which can be carried continuously by a conductor, a device or an apparatus, under specified conditions without its steady-state temperature exceeding a specified value".
The ampacity of a conductor depends on its ability to dissipate heat without damage to the conductor or its insulation. This is a function of the insulation temperature rating, the electrical resistance of the conductor material, the ambient temperature, and the ability of the insulated conductor to dissipate heat to the surrounds.
All common electrical conductors have some resistance to the flow of electricity. Electric current flowing through them causes voltage drop and power dissipation, which heats conductors. Copper or aluminum can conduct a large amount of current without damage, but long before conductor damage, insulation would, typically, be damaged by the resultant heat.
The ampacity for a conductor is based on physical and electrical properties of the material and construction of the conductor and of its insulation, ambient temperature, and environmental conditions adjacent to the conductor. Having a large overall surface area can dissipate heat well if the environment can absorb the heat.
In electrical cables different conditions govern, and installation regulations normally specify that the most severe condition along the run will govern each cable conductor's rating. Cables run in wet or oily locations may carry a lower temperature rating than in a dry installation. Derating is necessary for multiple cables in proximity. When multiple cables are in proximity, each contributes heat to the others and diminishes the amount of external cooling affecting the individual cable conductors. The overall ampacity of insulated cable conductors in a bundle of more than three cables must also be derated, whether in a raceway or cable. Usually the derating factor is tabulated in a nation's wiring regulations.
Depending on the type of insulating material, common maximum allowable temperatures at the surface of the conductor are 60, 75, and 90 °C, often with an ambient air temperature of 30 °C. In the United States, 105 °C is allowed with ambient of 40 °C, for larger power cables, especially those operating at more than 2 kV. Likewise, specific insulations are rated 150, 200, or 250 °C.
The allowed current in a conductor generally needs to be decreased (derated) when conductors are in a grouping or cable, enclosed in conduit, or an enclosure restricting heat dissipation. e.g. The United States National Electrical Code, Table 310.15(B)(16), specifies that up to three 8 AWG copper wires having a common insulating material (THWN) in a raceway, cable, or direct burial has an ampacity of 50 A when the ambient air is 30 °C, the conductor surface temperature allowed to be 75 °C. A single insulated conductor in free air has 70 A rating.
Ampacity rating is normally for continuous current, and short periods of overcurrent occur without harm in most cabling systems. Electrical code rules will give ratings for wiring where short-term loads are present, for example, in a hoisting motor. For systems such as underground power transmission cables, evaluation of the short-term over-load capacity of the cable system requires a detailed analysis of the cable's thermal environment and an evaluation of the commercial value of the lost service life due to excess temperature rise.
Design of an electrical system will normally include consideration of the current-carrying capacity of all conductors of the system.
Some devices are limited by power rating, and when this power rating occurs below their current limit, it is not necessary to know the current limit to design a system. A common example of this is lightbulb holders.
