Comparison Nitecore EDC31 vs Nitecore EDC33
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|---|---|---|
| Nitecore EDC31 | Nitecore EDC33 | |
| Compare prices 3 | Compare prices 1 | |
| User reviews | ||
| TOP sellers | ||
| Type | compact | compact |
Specs | ||
| Lamp type | lED with reflector | lED with reflector |
| Diode model | UHi 20 MAX | UHi 20 MAX |
| Peak luminous flux | 3500 lm | 4000 lm |
| Lighting range | 330 m | 450 m |
| Focus adjustment | ||
| Brightness levels | 6 | 6 |
| Light sensor | ||
Power supply | ||
| Power source | battery | battery |
| Battery capacity | 3800 mAh | 4000 mAh |
| Operating time (High mode) | 4 h | 2.5 h |
| Operating time (Low mode) | 24 h | 31 h |
| USB charging port | Type-C | Type-C |
| Charge level indicator | ||
In box | ||
| In box | battery(s) USB charging cable carrying clip strap | battery(s) USB charging cable carrying clip strap |
General | ||
| Shockproof | ||
| Water protection | IP68 | IP68 |
| Key lock | ||
| Material | metal | metal |
| Length | 11.3 cm | 11.6 cm |
| Weight | 100 g | 121 g |
| Color | ||
| Added to E-Catalog | july 2025 | june 2024 |
Compare Nitecore EDC31 and EDC33
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Glossary
Peak luminous flux
Luminous flux (measured in lumens) can be described as the total amount of light produced by an LED or other light source and emitted in all directions the source shines by itself. In practice, this means a flashlight’s capability depends not only on luminous flux but also on beam angle. For example, a relatively weak flux can be concentrated into a narrow beam to achieve good throw; while effectively covering a wide area will inevitably require a large number of lumens.
Peak luminous flux is the short-term maximum brightness a light source can deliver with a fresh battery and low temperature, usually in Turbo mode. It’s used to gauge instantaneous burst output. Unlike sustained (long-term) luminous flux, the peak lasts seconds or minutes and then drops due to heating down to High mode, so for real-world use it’s more important to understand how many lumens a flashlight can maintain steadily. You can see this with EDC models: a stated 2000 lm is impressive for a quick outdoor search, but for a long walk the device will switch, say, to 1000 lm, keeping a comfortable body temperature and solid runtime.
It’s also worth keeping in mind that high flashlight brightness is far from always justified, and you should choose this parameter based on real conditions of use. At short distances, very bright light can be a hindrance: it tires the eyes and can dazzle people nearby. In addition, increasing brightness usually requires more powerful sources of both light an...d power, so the flashlight’s weight and overall dimensions go up.
Peak luminous flux is the short-term maximum brightness a light source can deliver with a fresh battery and low temperature, usually in Turbo mode. It’s used to gauge instantaneous burst output. Unlike sustained (long-term) luminous flux, the peak lasts seconds or minutes and then drops due to heating down to High mode, so for real-world use it’s more important to understand how many lumens a flashlight can maintain steadily. You can see this with EDC models: a stated 2000 lm is impressive for a quick outdoor search, but for a long walk the device will switch, say, to 1000 lm, keeping a comfortable body temperature and solid runtime.
It’s also worth keeping in mind that high flashlight brightness is far from always justified, and you should choose this parameter based on real conditions of use. At short distances, very bright light can be a hindrance: it tires the eyes and can dazzle people nearby. In addition, increasing brightness usually requires more powerful sources of both light an...d power, so the flashlight’s weight and overall dimensions go up.
Lighting range
The maximum range at which the flashlight provides any effective illumination of objects. Different manufacturers have different criteria for this efficiency when measuring ranges, and therefore it is only possible to unequivocally compare among themselves in range only models of one manufacturer. At the same time, this parameter allows us to compare models from different manufacturers with some certainty: for example, flashlights with a lighting range of 15 m and 100 m will clearly belong to different range classes, regardless of manufacturers.
Note that the range of illumination depends not only on the maximum luminous flux provided by the lantern (see above), but also on the features of its design: the narrower the beam is provided by the reflector of the lantern, the greater the range will be, and vice versa — scattered light does not spread far. Some models allow you to adjust the beam width depending on the requirements of the situation (for more details, see "Adjusting the focus").
It is also worth bearing in mind that models with the same claimed lighting range can cover different spaces. For example, a hand lamp (see Type) with a reflector diameter of 20 cm will be able to provide a wider beam than a conventional hand lamp with a 5 cm reflector. And although in both cases the objects that fall into the light spot will be illuminated in the same way, however, in the first case, the size of the spot itself will be larger, and the actual efficien...cy of the flashlight will be correspondingly higher (in light of the fact that it is easier to "feel" individual objects with a wide beam, especially at a considerable distance).
Note that the range of illumination depends not only on the maximum luminous flux provided by the lantern (see above), but also on the features of its design: the narrower the beam is provided by the reflector of the lantern, the greater the range will be, and vice versa — scattered light does not spread far. Some models allow you to adjust the beam width depending on the requirements of the situation (for more details, see "Adjusting the focus").
It is also worth bearing in mind that models with the same claimed lighting range can cover different spaces. For example, a hand lamp (see Type) with a reflector diameter of 20 cm will be able to provide a wider beam than a conventional hand lamp with a 5 cm reflector. And although in both cases the objects that fall into the light spot will be illuminated in the same way, however, in the first case, the size of the spot itself will be larger, and the actual efficien...cy of the flashlight will be correspondingly higher (in light of the fact that it is easier to "feel" individual objects with a wide beam, especially at a considerable distance).
Light sensor
A sensor that monitors the level of ambient light. Used to automatically adjust the brightness of the flashlight to the environment — increase it in the dark when you need the brightest backlight and decrease it when the ambient light level rises. And when exposed to bright light, some of these models go into flashing mode — in order to warn the user and others that the flashlight is not turned off, and at the same time avoid unnecessary energy consumption.
Anyway, the light sensor optimizes battery consumption and improves battery life, without compromising the quality of lighting. On the other hand, this feature affects the cost of the device. Also note that for a number of reasons it is found mainly among headlamps (see "Type").
Anyway, the light sensor optimizes battery consumption and improves battery life, without compromising the quality of lighting. On the other hand, this feature affects the cost of the device. Also note that for a number of reasons it is found mainly among headlamps (see "Type").
Battery capacity
The capacity of the battery provided in the design or delivery of the flashlight.
Theoretically, a higher capacity allows to achieve greater battery life, but in fact, not everything is so simple. Firstly, the actual battery life will also depend on power consumption — and it can be different even in models with the same luminous flux (this is due to the difference in the characteristics of individual LEDs). Secondly, the physical features of the designation in milliamp-hours (mAh) are such that only batteries with the same nominal voltage can be directly compared by this indicator (in other cases, indicators must be recalculated using special formulas).
In light of all this, we can say that battery capacity is more of a reference than a practically significant parameter. So, in some cases, it allows you to compare different models of flashlights with each other, but only very approximately. For example, a device with a 1600 mAh battery will definitely have a longer battery life than a model with an 800 mAh battery that is similar in brightness, lamp type and “weight category”; but how much battery life will be higher is impossible to say for sure. So, in order to assess the practical capabilities of a flashlight, it is worth focus on more "close to life" characteristics — first of all, on the directly claimed maximum battery life (see above), as well as battery life indicators in different modes indicated in the manufacturer's documentation.
Theoretically, a higher capacity allows to achieve greater battery life, but in fact, not everything is so simple. Firstly, the actual battery life will also depend on power consumption — and it can be different even in models with the same luminous flux (this is due to the difference in the characteristics of individual LEDs). Secondly, the physical features of the designation in milliamp-hours (mAh) are such that only batteries with the same nominal voltage can be directly compared by this indicator (in other cases, indicators must be recalculated using special formulas).
In light of all this, we can say that battery capacity is more of a reference than a practically significant parameter. So, in some cases, it allows you to compare different models of flashlights with each other, but only very approximately. For example, a device with a 1600 mAh battery will definitely have a longer battery life than a model with an 800 mAh battery that is similar in brightness, lamp type and “weight category”; but how much battery life will be higher is impossible to say for sure. So, in order to assess the practical capabilities of a flashlight, it is worth focus on more "close to life" characteristics — first of all, on the directly claimed maximum battery life (see above), as well as battery life indicators in different modes indicated in the manufacturer's documentation.
Operating time (High mode)
Runtime at high “working” brightness High. Duration depends on the battery, driver quality (current stability), the body’s thermal conductivity, and conditions: in cold it lasts longer, in heat — shorter. Brightness–time graphs are useful for evaluation: in quality models the curve is smooth, without sudden drops. This mode is chosen for tasks that need powerful, steady light — hour-long repair jobs, trekking on a trail, bike rides, searching the yard; to extend runtime, choose a flashlight with a large battery and a hefty body with good cooling.
Operating time (Low mode)
The operating time in Low mode indicates how long the flashlight shines at low brightness before there’s a noticeable decrease in light level according to factory tests, usually at room temperature and with the battery provided. Low is chosen for long-duration tasks: set it as a tent light, attach it with a magnetic tail under the hood, or leave it as a nightlight or marker—situations where autonomy and moderate brightness are important. In this mode, the electronics heat up less and consume power more efficiently than in Medium/High, so the stated hours often reach the tens, especially in models with 18650/21700 batteries. It's important to consider that the actual "Low mode runtime" varies depending on the quality and capacity of the battery, outdoor temperature, and driver settings (such as whether there are steps and constant brightness maintenance). Compared to "Eco/Ultralow," Low provides a more practical level of light for household and service tasks, preserving the main advantage—long autonomy without overheating and unnecessary battery resource loss.
Key lock
The ability to block the flashlight control buttons.
This function ensures that the flashlight will not turn on in a pocket, bag, backpack, etc. and will not drain the battery by running "idle" during transportation. The specific implementation of the lock may be different, but most often it is turned on and off in a way that excludes accidents as much as possible — for example, by simultaneously pressing two buttons for a long time.
This function ensures that the flashlight will not turn on in a pocket, bag, backpack, etc. and will not drain the battery by running "idle" during transportation. The specific implementation of the lock may be different, but most often it is turned on and off in a way that excludes accidents as much as possible — for example, by simultaneously pressing two buttons for a long time.





