Comparison Oclean X Pro Elite vs Soocas X3

The number of power modes provided in the device. For flossing systems (see "Type"), this paragraph takes into account the characteristics of the irrigator; data on the toothbrush (if they differ) are indicated in the note.

It's important to distinguish between the number of power settings and the number of operating modes, as these are distinct parameters. Refer to the "Operating modes" section for details on the various modes. In this context, we emphasize that power adjustment, if available, may not be accessible in all modes. For example, in an irrigator offering two modes of operation—continuous jet and pulsation—power adjustment might only be available in the continuous jet mode.

Having multiple power settings enhances the versatility of the device. Even if a device technically offers only one operating mode, the ability to adjust the intensity of the treatment allows users to tailor the device for various tasks. For instance, in many toothbrushes, the traditional 2D brushing mode at its lowest power setting effectively serves as a gentle treatment option. However, it's worth noting that the capability to adjust power levels can somewhat increase the device's cost.

The brushing technology used by the toothbrush (see "Type").

In today's market, toothbrushes mainly feature cleaning technologies such as a href="/list/420/pr-14372/">reciprocating, reciprocating-sweeping, sonic and ultrasonic. The first two options can also include the additional feature of pulsating technology. The main difference between these methods lies in the nature of the movement of the bristles; Here is a more detailed description of each option:

— Reciprocating. This cleaning technology involves the bristles on brushes with round heads moving in a traditional manner. As the name suggests, the head rotates back and forth at a slight angle during operation. This technology is considered somewhat more advanced than reciprocating-sweeping, particularly because it offers improved cleaning in interdental and similar areas. However, it's important to note that brushes with this technology still don't match the efficiency of sonic and ultrasonic brushes but are generally more budget-friendly.

— Reciprocating-sweeping. Historically, this technology was the first to be used in brushes with oval nozzles. In brushes employing this principle, the bristles oscillate from left to right, resembling the motion of a broomstick—hence the name "reciprocating." Classic reciprocating brushes are characterized by a sim...ple design but are not particularly effective. Consequently, there are few such models available today, primarily found in low-cost devices. Most toothbrushes with oval heads now use more advanced sonic or ultrasonic technology.

— Pulsating. Usually, this term refers to the format of operating, in which the bristles move up and down relative to the surface of the nozzle, in other words, they go deep into the head and move back. This technology is rarely used in its pure form, it usually complements a reciprocating or reciprocating sweeping head, providing 3D cleaning capabilities (refer to "Modes"). But if the 3D mode is not claimed in the toothbrush, it is worth clarifying separately what is meant by pulsating technology. So, in some models, we are actually talking about the whitening mode, when, for maximum intensity of exposure, the device does not work constantly, but in separate pulses; in others, the term "pulsating" actually refers to the sonic or ultrasonic mode of operation.

— Sound. Sonic cleaning technology involves bristle vibrations with a small amplitude at a high frequency, reaching up to 40K vibrations per minute — this speed aligns with audible sound frequencies, hence the name "sonic." This cleaning method is considered more advanced than reciprocating and even reciprocating-sweeping technology. Sonic brushes, thanks to their high vibration speed, create a fine, uniform foam by mixing toothpaste, saliva, and air during cleaning. This foam can effectively penetrate hard-to-reach areas, and the vibrations themselves prove highly efficient at removing plaque, including from interdental spaces. While ultrasonic cleaning is considered even more advanced (as discussed below), sonic brushes are generally more affordable.

— Ultrasonic. Ultrasonic cleaning technology represents a further advancement of the sonic technology described earlier, distinguished primarily by a higher oscillation frequency. It's important to note that not all brushes in this category operate in the ultrasonic range; some models have oscillation frequencies that only slightly exceed 40K per minute, which is still within the range of audible sound. However, the operating frequency of such devices is significantly higher than that of standard sound devices. Ultrasonic technology offers several advantages, including thorough cleaning with access to hard-to-reach areas and a bactericidal effect. Ultrasound is capable of destroying bacteria responsible for plaque formation. However, brushes with this technology tend to be somewhat more expensive than their sonic counterparts.
It's important to mention that ultrasound technology is not as effective as conventional sound vibrations for cleaning braces and similar structures. As a result, some devices in this category incorporate both ultrasonic and conventional sound vibrations to ensure thorough cleaning in all situations.

The frequency of sound vibrations provided by a brush with a sonic or ultrasonic principle of operation (see "Cleaning technology").

A high oscillation frequency (from 40 000/min and above), ositively impacts the efficiency and quality of oral processing. In fact, brushes that generate more than 40,000 oscillations per minute are often referred to as ultrasonic brushes, although true ultrasound starts at much higher frequencies. However, it's important to note that these high-speed brushes tend to come with a higher price tag. It's also worth mentioning that for specific tasks, such as delicate treatment of sensitive teeth, relatively lower frequencies may be more suitable. Therefore, when choosing an oral care device, it's essential not to prioritize the maximum oscillation frequency but rather consider the individual needs of the user(s). Consulting a dentist for personalized recommendations is a prudent approach.

It's important to clarify that in this context, a full cycle of bristle movement is defined as one complete oscillation, which includes both the forward and backward motion. Some manufacturers employ a marketing tactic where they list their brush's operating frequency not in terms of complete oscillations but as the number of movements per minute, counting only half of the cycle — either the forward or backward motion. This can lead to impressive-sounding numbers in product specifications since the count of...movements is double the count of oscillations. However, the primary performance metric remains the number of complete cycles or oscillations, and that's the value provided in this section of our catalog.

The presence of an automatic frequency control in a toothbrush (sold separately or included in the delivery of the dental centre — see "Type").

This feature is exclusively present in sonic and ultrasonic toothbrush models, as mentioned in the "Cleaning Technology" section. The fundamental idea behind it is that the toothbrush automatically adjusts its oscillation frequency based on the selected mode. However, the specific implementation can vary. Some models operate only at predetermined frequency settings, while others offer manual adjustment of this parameter. There are also different control methods, such as the use of "smart" nozzles that trigger the corresponding mode automatically when attached. Regardless of the approach, automatic frequency control simplifies the user's experience by eliminating the need for unnecessary adjustments.

The presence of a pressure sensor in the device — a sensor that monitors the force with which the working nozzle is pressed against the teeth/gums.

This feature is primarily found in toothbrushes, including those that are part of flossing system units (as discussed in the "Type" section), but it can also be included in irrigators. Its primary function is to prevent potential harm to the teeth and gums caused by excessive pressure during brushing. The sensor's response can vary from one device to another; some devices emit a warning signal, while others reduce the bristle movement speed, and some may even shut off entirely in response to excessive pressure.

Having a pressure sensor in such devices can be beneficial not only for individuals with healthy teeth but also for those with heightened sensitivity or gum issues. It's a highly desirable feature for maintaining oral health. However, it's important to note that in many models, the pressure sensor is not integrated into the main body of the device but is instead part of the replaceable nozzle. Additionally, not all complete nozzle options may have this function, so it's essential to verify these details separately when choosing a device.

The presence of its own display in the design of the device.

These displays are typically small due to the compact size of the toothbrush or irrigator body. They usually offer basic functionality, capable of displaying one color and a limited set of characters. However, even with such constraints, they can convey various operational information, such as the selected mode, timer countdown, battery status, error messages, and more. As a result, these displays enhance overall convenience and visibility when using the device.

On the other hand, it's important to acknowledge that there's a growing number of models without displays, especially in the mid to high-end range. This shift is primarily driven by the widespread adoption of smartphone synchronization (as mentioned earlier), which offers several advantages over built-in screens. Firstly, the Bluetooth module required for synchronization is smaller and more cost-effective than a dedicated display. Secondly, smartphone screens and other control gadgets tend to be larger, more versatile, and easier to read compared to the small screens on toothbrush or irrigator handles. Additionally, the display on the device's handle is not visible during use, whereas a smartphone can be positioned in front of your eyes. As a result, it's worthwhile to seek out a model with this function if the ability to access data from a display is a crucial factor for you, regardless of whether you...have a smartphone or another additional device at hand.

Possibility of mounting the device on the wall.

The design of the mount for these devices depends on the device type (as mentioned earlier) and how it's typically used. In the case of most toothbrushes, which are typically self-powered, they come with a wall-mounted stand that also functions as a charger. Some irrigators and dental centers follow a similar setup, but many of these devices are designed for stationary use and have a larger main unit to which a handle with a nozzle attaches. In such models, the wall mount is designed to accommodate the entire main unit.

Wall installation offers a significant advantage by saving shelf space, which is particularly beneficial in tight spaces. However, this installation method entails additional preparatory work, which can be somewhat challenging. Furthermore, not all wall mounts facilitate easy removal and installation of the device, making it less suitable for situations where you frequently need to take the toothbrush or irrigator with you on trips.

This refers to the maximum duration a device can run continuously when powered by a fully charged battery or fresh batteries. It's worth noting that this metric may also apply to models designed for mains power, such as flossing systems that include rechargeable toothbrushes, in which case we're referring to the battery life of these toothbrushes.

It's important to note that device specifications typically indicate the maximum runtime under ideal conditions, often in the most energy-efficient mode of operation (and for models with replaceable batteries, using high-quality batteries). The actual battery life can vary depending on specific usage conditions. However, this parameter still serves as a valuable basis for comparing different models. Generally, differences in the claimed operating time correspond proportionally to the real differences in battery life. For example, if one toothbrush has a stated operating time of 20 minutes and another boasts 40 minutes, in practice, their battery life (under similar conditions) will likely differ by approximately two times.

It's important to consider that, for toothbrushes, this parameter can help estimate the number of brushing sessions you can expect on a single charge. Typically, the recommended daily brushing duration is 2 minutes. So, if a toothbrush has an operating time of 30 minutes, it's sufficient for approximately 15 cleaning sessions (or more realistically, around 14 or 13).

The time required to charge the battery from zero to 100% in a device with the appropriate power type (see above). This parameter can vary from 1 – 3 hours in relatively simple and low-power devices to a day in advanced models with capacious batteries. At the same time, the longer the maximum operating time on a charge (see above), the longer, usually, the time required for charging, although there is no hard dependence here.

In general, having fast charging capabilities improves the convenience of a device by reducing interruptions in its operation. However, there is a trade-off to consider: fast charging often means either a smaller battery capacity or a higher price due to the use of specialized technologies to speed up the charging process. When evaluating this parameter, it's essential to think about how you intend to use the device. For instance, if a toothbrush or irrigator is solely used at home by one person and comes with a charging stand, fast charging may not be a critical factor. The device remains consistently charged as it's constantly on the charger, and its battery doesn't deplete significantly during one use. The time between sessions, usually around 8 to 12 hours, is more than enough to maintain a charged battery, even for devices with slower charging. However, if you plan to use the device while traveling, where access to power outlets is sporadic, it's preferable to have minima...l charging time to ensure you can recharge quickly during your trips.