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Comparison RGK LP-62G vs Crown CT44022 BMC

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RGK LP-62G
Crown CT44022 BMC
RGK LP-62GCrown CT44022 BMC
Outdated ProductOutdated Product
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Typelaser levellaser level
Specs
Measurement range30 m30 m
Accuracy0.2 mm/m0.15 mm/m
Self-leveling angle4 °3 °
Leveling time5 с
Operating temperature-10 – 45 °C-10 – 50 °C
Tripod thread5/8"5/8"
Laser characteristics
Diode emission532 nm525 nm
Laser colourgreengreen
Laser class2M2
Vertical projections21
Beam angle (vertical)120 °
Horizontal projections11
Beam angle (horizontal)110 °
Point projections11
Nadir
Features
Compensator locking
Spirit level
General
IP protection rating5454
Power sourceAA x3 or batterybattery
Mains powered
In box
tribrach
case / pouch
battery
charger
glasses
tribrach
case / pouch
 
charger
glasses
Dimensions150x150x190 mm245x228x190 mm
Weight1100 g1030 g
Added to E-Catalogdecember 2019april 2019

Accuracy

Accuracy is described as the maximum deviation from the true value of the measured parameter, which the device can give if all the rules for its operation and the corresponding measurements are observed. In both rangefinders and levels, this parameter is usually designated for a certain distance — for example, 3 mm at 30 m; but even for one manufacturer, these "control" distances may be different. Therefore, in our catalog, the accuracy of all devices is recalculated for 1 m distance; with such a record, for the example above, it will be 3/30 \u003d 0.1 mm / m. This makes it easier to compare different models with each other.

It is also worth mentioning that the meaning of the "accuracy" parameter for different types of measuring instruments (see "Type") will be different. For optical levels, it is described in the "SKP" paragraph above. For laser levels of all types, accuracy is the maximum deviation of the mark from the true horizontal (or vertical, if such a function is provided), and for the horizontal, we can talk about both moving the mark up / down and turning it. In rangefinders, this characteristic describes the maximum difference (both in "plus" and "minus") between the readings of the device and the actual distance to the object.

Anyway, the smaller the error, the better; on the other hand, accuracy significantly affects the price of the device. Therefore, it is necessary to choose a specific model for this parameter, taking into account the...specifics of the planned work. For example, for a relatively simple repair in a residential apartment, a high-precision tool is unlikely to be required; and recommendations for more complex tasks can be found in specialized sources, ranging from expert advice to official instructions.

Self-leveling angle

The maximum deviation from the horizontal position that the device is able to correct "by its own means".

Self-leveling in itself greatly simplifies the installation and initial calibration of levels (see "Type"), which often (and for optical models — mandatory) need to be set horizontally to work. With this function, it is enough to install the device more or less evenly (in many models, special devices are provided for this, such as round levels) — and fine tuning in the longitudinal and transverse planes will be carried out automatically. And the limits of self-leveling are usually indicated for both planes; the higher this indicator, the easier the device is to install, the less demanding it is to the initial placement. In some models, this figure can reach 6 – 8 °.

Leveling time

Approximate time it takes for the self-levelling mechanism to bring the level to a perfectly level position.

For more information on such a mechanism, see Self-Level Limits. And the actual time of its alignment directly depends on the actual deviation of the device from the horizontal. Therefore, in the characteristics, usually, the maximum alignment time is given — that is, for the situation when in the initial position the device is tilted to the maximum angle along both axes, longitudinal and transverse. Since the levels are far from being installed in this position, in fact the speed of bringing to the horizontal is often higher than the claimed one. Nevertheless, it makes sense to evaluate different models precisely according to the figures stated in the characteristics — they allow you to estimate the maximum amount of time that will have to be spent on alignment after the next movement of the device. As for specific indicators, they can vary from 1.5 – 2 s to 30 s.

Theoretically, the shorter the alignment time, the better, especially if there are large volumes of work ahead with frequent movements from place to place. However, in fact, when comparing different models, it is worth considering other points. First, we reiterate that the rate of leveling is highly dependent on the leveling limits; after all, the greater the deviation angles, the more time it usually takes for the mechanism to return the level to the horizontal. So, to directly compare w...ith each other in terms of the speed of self-leveling, it is mainly those devices in which the permissible deviation angles are the same or differ slightly. Secondly, when choosing, it is worth considering the specifics of the proposed work. So, if the device is to be used frequently on very uneven surfaces, then, for example, a model with a leveling time of 20 s and self-levelling limits of 6 ° will be a more reasonable choice than a device with a time of 5 s and limits of 2 °, since in In the second case, a lot of time will be spent on the initial (manual) installation of the device. And for more or less even horizontal planes, on the contrary, a faster device may be the best option.

Operating temperature

The temperature range at which the device is guaranteed to work for a sufficiently long time without failures, breakdowns and exceeding the measurement error specified in the characteristics. Note that we are talking primarily about the temperature of the device case, and it depends not only on the ambient temperature — for example, a tool left in the sun can overheat even in fairly cool weather.

In general, you should pay attention to this parameter when you are looking for a model for working outdoors, in unheated rooms and other places with conditions that are significantly different from indoor ones; in the first case, it makes sense to also make sure that there is dust and water protection (see "Protection class"). On the other hand, even relatively simple and "myopic" levels / rangefinders usually tolerate both heat and cold quite well.

Diode emission

The wavelength of the radiation emitted by the LED of the level or rangefinder; this parameter determines primarily the colour of the laser beam. The most widespread in modern models are LEDs with a wavelength of about 635 nm — at a relatively low cost, they provide bright red radiation, giving a well-visible projection. There are also green lasers, usually at 532 nm — the marks from them are even better visible, but such LEDs are quite expensive and rarely used. And radiation with a wave longer than 780 nm belongs to the infrared spectrum. Such a laser is invisible to the naked eye and is poorly suited for leveling, but it can be used in rangefinders — of course, with a viewfinder (see "Type" for more details).

Laser class

Class of the laser emitter installed in the device.

The laser power primarily depends on this indicator; and this, in turn, affects the effective range of the device and precautions when working with it. The main options relevant for modern levels and rangefinders are class 2, class 2M and class 3R, here is their more detailed description:

— 2. Such a laser beam is considered safe in case of accidental contact with the eyes, since due to the blinking reflex, the exposure time in such cases usually does not exceed a quarter of a second. This applies to both the naked eye and the use of magnifying instruments such as a monocular or even a telescope. But constant exposure to the eye already poses a danger to vision. The power of such emitters should be below 1 mW. In fact, 2 is the lowest (in terms of power) class used in levels and rangefinders; weaker lasers of classes 1 and 1M simply do not provide the required efficiency. Such emitters are used in the vast majority of low and medium power devices.

- 2M. Such lasers produce a wider beam than class 2 emitters. However, such a beam is also considered safe if it accidentally enters the eye - but only if we are talking about the naked eye. When viewed through a monocular or other magnifying optical instrument, class 2M lasers are dangerous even with low-term (fractions of a second) exposure to the eye. I...n general, this option is quite rare: class 2M is not strictly official and does not have such clear criteria as the original class 2.

- 3R. Also known as IIIa. In fact, it is an analogue of class 2, suggesting a higher emitter power, namely from 1 to 4.99 mW. At the same time, class 3R lasers are generally considered safe in case of accidental contact with the eye when a person reflexively blinks or turns away and the exposure time does not exceed ¼ second. However, such emitters carry a greater risk of serious harm to health than Class 2 devices, so greater caution should still be exercised when using them.

Vertical projections

The number of vertical projections issued by the laser level during operation.

Most modern levels are designed for a strictly defined position when working; accordingly, the projection is called vertical, carried out from top to bottom relative to the standard position of the device. If there are several such planes, the level can be used for two or even three walls at once — this is useful, for example, for the simultaneous work of several people. At the same time, there are portable devices that can be used in different positions; for them, the main working plane is called vertical, although during operation it can be located both horizontally and at an angle, depending on specific tasks. Also note that the vertical projection can also give a horizontal line — for example, when installing a level on the floor.

Note that the number of projections is calculated not by geometric planes, but by individual laser elements, each of which is responsible for its own “work area”. For example, if the level has two vertical elements located at opposite ends and directed in different directions, they are considered as two projections even if these projections lie in the same plane.

Beam angle (vertical)

The sweep angle in the vertical plane provided by the level emitter. If there are several such radiators (for example, on both sides of the case), this parameter is given for each of them separately.

The sweep angle is, in fact, the coverage angle, that is, the width of the sector captured by the emitter when the line is formed. The wider this angle, the more convenient the device is to use, the lower the likelihood that the device will have to be moved up and down to build a line. On the other hand, a larger sweep angle (at the same range) requires more power — and this, accordingly, affects the cost and power consumption.

Beam angle (horizontal)

The sweep angle in the horizontal plane provided by the level emitter. If there are several emitters, their total coverage angle is indicated here; a typical example of such devices are models for full 360 °, not related to rotation.

Actually, all rotary devices, by definition, provide a coverage of 360 °. Therefore, it is worth paying attention to this parameter in cases where we are talking about more traditional laser levels. And here it is worth considering that a larger coverage angle, on the one hand, can provide additional convenience, on the other hand, it increases the price and power consumption of the device. So when choosing, you should proceed from real needs; detailed recommendations on this subject can be found in special sources.