CN113599005A - Electric toothbrush with rotary resonance motor - Google Patents

Abstract

The invention provides at least one electric toothbrush with a rotary Resonant Motor (RMT), in particular at least for cleaning and caring teeth, and/or between teeth, and/or the oral cavity, comprising at least a housing (EH), an actuating device (ED), a rotary Resonant Motor (RM), and/or a transmission device (TM), and/or a Controller (CS), and/or a battery (EB), and/or a detection device, and/or a vibration damping Device (DP), wherein the housing (EH) is directly or indirectly combined and connected with the module or the device, so as to realize the tooth cleaning and caring functions. Compared with the prior art, the electric toothbrush is driven by the rotary resonance motor, so that the multifunctional electric toothbrush has multiple functions, small hand feeling vibration and good use experience of users.

Description

Electric toothbrush with rotary resonance motor

Technical Field

The present invention relates to at least one electric toothbrush with a rotating resonant motor, in particular an electric toothbrush with a rotating resonant motor for at least the cleaning and care of the teeth, and/or the crevices of the teeth, and/or the oral cavity.

Background

Electric toothbrush products are becoming more and more common in people's lives today. Some of current many electric toothbrush products adopt the rotating electrical machines to drive the brush head vibration through a series of drive mechanism, and some adopt the rotating electrical machines to drive the brush head vibration through a series of drive mechanism to realize the clean tooth effect. However, both driving modes are unavoidable to generate vibration and noise, and generally, the higher the tooth brushing strength is, the more obvious the hand feeling vibration and noise of the electric toothbrush are, thereby causing the user to experience bad feeling.

Therefore, the hand feeling vibration of the electric toothbrush is reduced to the maximum extent by various vibration reduction methods, which is a problem to be solved urgently by the existing electric toothbrush products.

The spring oscillator system is a conceptual model in physics, and has resonance behavior under the action of periodic external force. The rotary resonance motor can be structurally divided into a vibrator and a stator. The oscillator and the stator have a certain gap, the stator is fixedly installed on the support, the oscillator is connected with the support through the spring, the spring has a certain stiffness coefficient and a damping coefficient, and the oscillator and the stator can interact through electromagnetic force. The vibrator, spring and support system can basically be described as a rotary vibration type spring vibrator system, which has a rotary resonance behavior under the action of a periodic electromagnetic force. This results in a high drive efficiency of the rotating resonant motor when driven at its resonant frequency and within its resonant frequency range.

Disclosure of Invention

The invention is made based on the comprehensive solution of the problem of larger hand feeling vibration of the existing electric toothbrush products. The present invention is directed to at least one electric toothbrush having a rotating resonant motor.

The invention is realized by the following scheme:

electric toothbrush RMT with a rotating resonant motor, comprising at least: the housing EH, the actuator ED, the rotating resonance machine RM, and/or the transmission TM, and/or the controller CS, and/or the battery EB, and/or the detection device, and/or the vibration damping device DP.

Further, between the resonance motor RM and the actuator ED, the transmission TM is configured to function as at least one transmission ratio. And/or between said resonant electric machine RM and said actuator ED, said transmission TM being configured at least to function with a transmission ratio varying over a range of ratios. And/or between the resonant electric machine RM and the actuator ED, the transmission TM is configured to function with at least two transmission ratios. And/or between the resonant electric machine RM and the actuator ED, the transmission TM is configured to function with at least three transmission ratios. And/or between said resonant electric machine RM and said actuator ED, said transmission TM is configured to function with at least four transmission ratios. And/or between the resonant electric machine RM and the actuator ED, the transmission TM is configured to function with at least five transmission ratios. And/or between the resonant electric machine RM and the actuator ED, the transmission TM is configured to function with at least six transmission ratios. And/or between the resonant electric machine RM and the actuator ED, the transmission TM is configured to function with at least seven transmission ratios. And/or between said resonant electric machine RM and said actuator ED, said transmission TM is configured to function with at least eight transmission ratios. And/or the transmission TM is equipped with at least a first overrunning clutch FC1, and/or a second overrunning clutch FC2, and/or a first clutch C1, and/or a second clutch C2, and/or a third clutch C3, and/or a fourth clutch C4. And/or

Further, the electric toothbrush RMT with the rotating resonance motor is configured to have at least one electric toothbrush operation mode. In the electric toothbrush operating mode, the actuator ED can be selectively vibrated, and/or oscillated, and/or rotated, and/or moved. And/or the tooth brush head can be selectively vibrated, and/or oscillated, and/or rotated, and/or moved. So that the electric toothbrush RMT having the rotary resonance motor can clean teeth under the manipulation of the user. And/or the user can selectively adjust at least the intensity, and/or frequency, of teeth cleaning by the applicator ED within a certain range. And/or

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one electric interdental brush mode of operation. In the electric toothbrush operating mode, the actuator ED may be selectively vibrated, and/or oscillated, and/or rotated, and/or moved. And/or the interdental brush may be selectively vibrated, and/or oscillated, and/or rotated, and/or moved. So that the electric toothbrush RMT having the rotary resonance motor can clean the interdental space under the manipulation of the user. And/or the user can selectively adjust at least the intensity, and/or the frequency of cleaning crevices between teeth to a certain extent. And/or

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one electric orthodontic brush mode of operation. In the operating mode of the electric orthodontic brush, the actuator ED can selectively oscillate, and/or rotate, and/or move. And/or the orthodontic brush may be selectively vibrated, and/or oscillated, and/or rotated, and/or moved. Such that the electric toothbrush RMT with the rotating resonant motor can clean the teeth and/or dental appliances under the user's manipulation. And/or the user can selectively adjust at least the intensity, and/or frequency of cleaning teeth and/or dental appliances over a range. And/or

The electric toothbrush RMT with a rotating resonant motor is configured with at least one gum care mode of operation. In the gum care mode of operation, the actuator ED selectively massages the gums. And/or the massage head can selectively massage the gum. So that the electric toothbrush RMT having the rotary resonance motor can massage or care for gums under the manipulation of the user. And/or the user can at least selectively adjust the massage frequency and/or the massage intensity of the massage head within a certain range. And/or

The electric toothbrush RMT with a rotating resonant motor is configured with at least one oral care mode of operation. In the oral care mode of operation, the actuator ED may selectively massage the mouth. And/or the massage head can selectively massage the oral cavity. So that the electric toothbrush RMT having the rotary resonance motor can massage or care for the oral cavity under the manipulation of the user. And/or the user can selectively adjust at least the massage frequency and/or the massage intensity of the actuator ED within a certain range. And/or the user can at least selectively adjust the massage frequency and/or the massage intensity of the massage head within a certain range. And/or

The electric toothbrush RMT with a rotating resonant motor is configured with at least one three-dimensional scanning and modeling mode of operation. In the three-dimensional scanning and modeling operation mode, the execution device ED can selectively perform three-dimensional scanning on teeth, slits between teeth and gums and establish corresponding three-dimensional models under the direct or indirect action of the controller CS, and the three-dimensional scanning data and the three-dimensional model data can be stored, transmitted and edited. And/or

The electric toothbrush RMT with a rotating resonant motor is configured with at least one visual mode of operation. In the visual working mode, the executing device ED can selectively display, enlarge, reduce, and/or virtually display, and/or capture and/or record the target object in real time under the direct or indirect action of the controller CS, and the related data can be stored, transmitted and edited. And/or

The electric toothbrush RMT with a rotating resonant motor is configured with at least one endoscopic mode of operation. In the endoscopic operation mode, the actuator ED can selectively enlarge and display the oral cavity and/or pores under the direct or indirect action of the controller CS, and can display, screen shot and/or record in real time, and the related data can be stored, transmitted and edited. And/or

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one human-machine interaction mode of operation. In the human-machine interaction working mode, the controller CS may selectively give an operation prompt message and/or selectively give an operation result message and/or selectively give an operation evaluation effect and/or selectively charge the battery EB, according to the user input, and/or the feedback of the actuator ED, and/or the feedback of the detector EH, and/or the feedback of the rotary resonant motor RM, and/or the feedback of the motor mount FB, and/or the feedback of the damper DP, and/or the feedback of the transmission TM, and/or the self-feedback of the controller CS, and/or the feedback of the battery EB, and/or the feedback of the electric power EP, And/or optionally giving a health assessment result, and/or optionally giving a cleanliness assessment result. And/or

The electric toothbrush RMT with the rotating resonance motor is configured to have at least one standby operation mode. In the standby mode of operation, the controller CS, and/or the actuator ED, and/or the rotating resonance machine RM, and/or the damping device DP, and/or the transmission TM, and/or the battery EB are in a standby state. And/or

The electric toothbrush RMT having the rotary resonance motor is configured to have at least one failure mode. In the failure mode, the function of the partial module of the electric toothbrush with a rotational resonance motor RMT is limited, and the electric toothbrush with a rotational resonance motor RMT may selectively give a failure code, and/or a notice message, and/or a failure message. And/or

The electric toothbrush RMT with a rotating resonant motor comprises at least one control system. And/or

The controller CS comprises at least one control system. And/or

Under the direct or indirect action of said controller CS, and/or of said control system, said electric toothbrush RMT with rotating resonant motor is configured at least to function selectively in different operating modes, according to said user input, and/or to the feedback of said actuating device ED, and/or to the feedback of said detecting device EH, and/or to the feedback of said rotating resonant motor RM, and/or to the feedback of said motor support FB, and/or to the feedback of said damping device DP, and/or to the feedback of said transmission TM, and/or to the feedback of said controller CS, and/or to the feedback of said battery EB, and/or to the feedback of said electric power EP.

Compared with the prior art, the invention has the following advantages:

1. one machine has multiple functions: the invention integrates the functions of an electric toothbrush, an electric interdental brush and an electric orthodontic brush, and can realize the functions of cleaning and nursing teeth, and/or interdental spaces and/or oral cavities by replacing different execution devices.

2. The hand feeling vibration is small, the use experience is good: the invention adopts the rotary resonance motor as a power source, the rotary resonance motor has higher driving efficiency when being driven in the resonance frequency and the resonance frequency range, and the executing device can be driven by utilizing the vibration characteristic of the rotary resonance motor, so that most vibration energy can be used for driving the executing device to clean teeth, and/or slits between teeth and/or oral cavity. The vibration characteristic of the spring vibrator system can be utilized to absorb vibration so as to achieve the purpose of damping the connected parts. The spring vibrator system can effectively absorb the vibration of the mounting bracket of the spring vibrator system in the resonant frequency and the resonant frequency range, so that the vibration transmitted to other connected parts through the mounting bracket is obviously reduced. In addition, adopt damping device further to reduce the feel vibration and the noise of ear sense of casing for user's use experiences and feels better.

The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings, wherein, however, it is to be expressly understood that all of the figures are for the purpose of illustration only and are not intended as a definition of the limits and scope of the invention.

Drawings

Fig. 1 to 9 are schematic views of electric toothbrushes having a rotational resonance motor according to embodiments 1 to 9, respectively. Fig. 10 to 17 are schematic views of technical solutions of the transmission device, respectively. The notation in the figure is: RMT-electric toothbrush with rotary resonance motor, EH-case, ED-actuator, RM-rotary resonance motor, TM-transmission, FB-motor holder, DP-vibration damping device, CS-controller, EB-battery, EP-power (external power source), FC 1-first overrunning clutch, FC 2-second overrunning clutch, C1-first clutch, C2-second clutch, C3-third clutch, C4-fourth clutch, T1-first transmission shaft, T2-second transmission shaft, T3-third transmission shaft, T4-fourth transmission shaft, P1-first driving gear, P2-second driving gear, P3-third driving gear, P4-fourth driving gear, P5-fifth driving gear, p6-sixth driving gear, P7-seventh driving gear, P8-eighth driving gear, W1-first driven gear, W2-second driven gearThe gear comprises a gear body, W3, a third driven gear, W4, a fourth driven gear, W5, a fifth driven gear, W6, a sixth driven gear, W7, a seventh driven gear, W8, an eighth driven gear, G1, a first transmission gear, G2, a second transmission gear and G3, wherein the gear body is a gear body. In the drawings, there is shown in the drawings,

representing an electrical connection, and/or a signal connection,

indicating a mechanical connection.

Detailed Description

The invention is further illustrated by the following figures and examples, but the invention is not limited to the examples. It is to be understood that only a few preferred embodiments of the present invention have been described, and not all embodiments have been described. Since numerous changes in the principles of the invention will readily occur to those skilled in the art, it is not desired to limit the invention to the exact details shown and described, but rather, to all changes and modifications that may be resorted to, falling within the scope of the appended claims.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting. As used herein, the singular forms "a", "an", and the like may also be intended to include the plural forms as well, unless the context clearly indicates otherwise. The terms "comprises" and "comprising" are inclusive and therefore specify the presence of stated features, integers, steps, operations, elements, components, parts, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. The method steps, procedures and operations described herein should not be construed as necessarily requiring their performance in the particular order discussed or illustrated, unless specifically identified as an order of performance. It should also be understood that additional or alternative steps may be employed.

Although the terms first, second, third, etc. may be used herein to describe various parts, components, assemblies, layers and/or sections, these parts, components, assemblies, layers and/or sections should not be limited by these terms. These terms may be only used to distinguish one element, component, member, component, layer and/or section. Terms such as "first," "second," "third," and other numerical terms when used herein do not imply a sequence or order unless clearly indicated by the context.

Example 1

An electric toothbrush RMT with a rotating resonant motor, as shown in fig. 1, comprises: a housing EH, a controller CS, a battery EB, a rotating resonance motor RM, and an actuator ED.

In the drawings, there is shown in the drawings,

representing an electrical connection, and/or a signal connection,

indicating a mechanical connection, and/or a hydraulic conduit connection.

The controller CS, the rotational resonance motor RM, and the battery EB are disposed in the case EH. The actuator ED is disposed outside the housing EH, and the actuator ED is connected to the housing EH. The housing EH is at least configured as a base, and/or a mounting, and/or a connecting, and/or a supporting, and/or a fixing, and/or a peripheral envelope of the electric toothbrush RMT with a rotating resonant motor. The rotational resonance motor RM is a power source of the electric toothbrush RMT having the rotational resonance motor. The rotational resonance motor RM is connected to the electric power EP. The electric power EP is an external power supply.

The rotational resonance motor RM has a function of converting the electric power EP into rotational vibration of the rotational resonance motor RM. And/or the rotational resonance motor RM has a function of generating rotational vibration using the electric power EP. And/or the rotational resonance motor RM has a function of generating mechanical energy of rotational vibration using electric energy of the electric power EP. The actuating device ED has the function of cleaning or caring for the teeth. And/or the actuator ED has the function of cleaning or caring for interdental spaces. And/or the actuating device ED has the function of cleaning or caring for the oral cavity. And/or the actuating device ED has the function of cleaning or caring the orthodontic retainer. And/or the actuator ED has the function of massaging the gums. And/or the actuator ED has the function of massaging the oral cavity. The battery EB has a function of storing electric energy.

The rotational resonance motor RM is connected to the controller CS, and the rotational resonance motor RM can selectively drive the electric toothbrush RMT having the rotational resonance motor by the controller CS. The rotating resonance motor RM is connected with the actuator ED, and the actuator ED can clean or care teeth, and/or slits between teeth, and/or oral cavity under the driving of the rotating resonance motor RM, and/or the actuator ED can massage gingiva and/or oral cavity under the driving of the rotating resonance motor RM. The actuator ED is connected to the controller CS through the rotational resonance motor RM, and the actuator ED can selectively clean or care teeth, and/or slits between teeth, and/or oral cavity by the controller CS and the rotational resonance motor RM, and/or the actuator ED can selectively massage gums and/or oral cavity by the controller CS and the rotational resonance motor RM.

The battery EB is connected to the power EP through the controller CS. Under the action of the controller CS, the battery EB can be selectively charged and discharged. Under the action of the controller CS, the battery EB can selectively store electric energy of the electric power EP. The rotational resonance motor RM is connected to the electric power EP through the controller CS. Under the action of the controller CS, the electric power EP may selectively supply electric energy to the rotational resonance motor RM. The rotational resonance motor RM is connected to the battery EB through the controller CS. Under the action of the controller CS, the battery EB can selectively supply electric energy to the rotational resonance motor RM.

The electric toothbrush RMT having the rotational resonance motor can selectively drive the actuator ED by the rotational vibration generated from the rotational resonance motor RM to perform a function of cleaning or caring for teeth, and/or slits between teeth, and/or an oral cavity. Alternatively, the electric toothbrush RMT with the rotational resonance motor may selectively use the rotational vibration generated by the rotational resonance motor RM to drive the actuator ED to achieve the function of massaging the gums and/or massaging the oral cavity.

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one electric toothbrush mode of operation. In the electric toothbrush operating mode, the actuator ED is selectively vibrated, and/or oscillated, and/or rotated, and/or moved, so that the electric toothbrush RMT with the rotating resonant motor can clean the teeth under the user's manipulation. The user can selectively adjust at least the intensity, and/or frequency, at which the applicator ED cleans the teeth within a certain range.

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one electric interdental brush mode of operation. In the electric interdental brush operation mode, the actuator ED may be selectively vibrated, and/or oscillated, and/or rotated, and/or moved, so that the electric toothbrush RMT having the rotational resonance motor may clean interdental spaces under the manipulation of the user. The user can selectively adjust at least the intensity, and/or frequency of cleaning crevices between teeth to a certain extent.

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one electric orthodontic brush mode of operation. In the electric orthodontic brush mode of operation, the actuator ED may be selectively vibrated, and/or oscillated, and/or rotated, and/or moved, such that the electric toothbrush RMT with the rotating resonant motor may clean teeth and/or appliances under the user's manipulation. The user can selectively adjust at least the intensity, and/or frequency of cleaning teeth and/or dental appliances over a range.

The electric toothbrush RMT with a rotating resonant motor is configured with at least one gum care mode of operation. In the gum care operation mode, the actuator ED can selectively massage the gums so that the electric toothbrush RMT having the rotary resonant motor can massage or care for the gums under the manipulation of the user. The user can selectively adjust at least the massage frequency and/or the massage intensity of the massage head within a certain range.

The electric toothbrush RMT with a rotating resonant motor is configured with at least one oral care mode of operation. In the oral care mode of operation, the actuator ED selectively massages the oral cavity so that the electric toothbrush RMT with the rotating resonant motor massages or cares for the oral cavity when manipulated by the user. The user can selectively adjust at least the massage frequency and/or the massage intensity of the actuator ED within a certain range.

The electric toothbrush RMT with a rotating resonant motor is configured to have at least one human-machine interaction mode of operation. In the human-computer interaction mode, the controller CS may selectively give an operation prompt message and/or selectively give an operation result message and/or selectively give an operation evaluation effect according to the user input and the feedback of the rotational resonance motor RM.

The electric toothbrush RMT with the rotating resonance motor is configured to have at least one standby operation mode. In the standby operation mode, the controller CS and the rotational resonance motor RM are in a standby state.

The electric toothbrush RMT having the rotary resonance motor is configured to have at least one failure mode. In the failure mode, the function of the partial module of the electric toothbrush with a rotational resonance motor RMT is limited, and the electric toothbrush with a rotational resonance motor RMT may selectively give a failure code, and/or a notice message, and/or a failure message.

The controller CS comprises at least one control system. The electric toothbrush with a rotational resonance motor RMT is configured to have at least a function of selectively adopting different operation modes according to the user's input, and/or the feedback of the rotational resonance motor RM, and/or the feedback of the controller CS, by the controller CS.

Example 2

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 2, is similar in construction to embodiment 1 except that: in embodiment 2, the transmission TM is added; the transmission device TM is arranged in the shell EH and is directly or indirectly connected with the shell EH; the transmission TM is configured to have at least a function of transmitting power; and/or the transmission TM is configured to function as at least one transmission ratio; and/or the transmission TM is configured to function at least as a plurality of transmission ratios; and/or the transmission TM is configured to transmit power at least over a range of transmission ratios; and/or the transmission TM has a self-shifting function; and/or the transmission TM is configured to have at least a function of manual shifting.

The transmission device TM has several typical structures as shown in FIGS. 10-17.

The transmission TM, as shown in fig. 10, comprises: a first transmission shaft T1, a second transmission shaft T2, a first driving gear P1 and a first driven gear W1. The first driving gear P1 is connected to the rotational resonance motor RM through the first transmission shaft T1. The first driven gear W1 is connected with the actuator ED through the second transmission shaft T2. The first driving gear P1 is engaged with the first driven gear W1. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED.

The transmission TM, as shown in fig. 11, includes: the transmission mechanism comprises a first transmission shaft T1, a second transmission shaft T2, a third transmission shaft T3, a first driving gear P1, a second driving gear P2, a first driven gear W1, a second driven gear W2, a third driven gear W3, a first overrunning clutch FC1 and a second overrunning clutch FC 2. The first transmission shaft T1 is connected to the rotational resonance motor RM. The first transmission shaft T1 is connected to the first driving gear P1 through the first overrunning clutch FC 1. The first transmission shaft T1 is connected to the second driving gear P2 through the second overrunning clutch FC 2. And the locking direction of the first overrunning clutch FC1 is opposite to the locking direction of the second overrunning clutch FC 2. The first driven gear W1 and the second driven gear W2 are both connected with the actuator ED through the second transmission shaft T2. The third driven gear W3 is coaxially connected with the third transmission shaft T3. The first driving gear P1 and the third driven gear W3 are engaged with each other. The third driven gear W3 is intermeshed with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. When the rotational resonance motor RM rotates reversely to input power, the second overrunning clutch FC2 is unlocked, and the first overrunning clutch FC1 is locked, so that the rotational resonance motor RM drives the actuator ED to operate at a first gear transmission ratio. When the rotating resonance motor RM positively rotates to input power, the second overrunning clutch FC2 is locked, the first overrunning clutch FC1 is unlocked, and the rotating resonance motor RM drives the actuating device ED to operate at a second gear transmission ratio. Under the action of the transmission TM, the rotating resonance motor RM can drive the actuator ED selectively at two transmission ratios.

The transmission TM, as shown in fig. 12, includes: the transmission mechanism comprises a first transmission shaft T1, a second transmission shaft T2, a first driving gear P1, a second driving gear P2, a first driven gear W1, a second driven gear W2 and a first clutch C1. The first driving gear P1 and the second driving gear P2 are connected to the rotational resonance motor RM through the first transmission shaft T1. The second transmission shaft T2 is connected to the actuator ED. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transfer shaft T2 through the first clutch C1. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. Under the action of the transmission TM, the rotating resonance electric machine RM can selectively drive the actuator ED at two transmission ratios.

The transmission TM, as shown in fig. 13, comprises: the transmission mechanism comprises a first transmission shaft T1, a second transmission shaft T2, a third transmission shaft T3, a fourth transmission shaft T4, a first driving gear P1, a second driving gear P2, a first driven gear W1, a second driven gear W2, a third driven gear W3, a fourth driven gear W4, a first transmission gear G1, a second transmission gear G2, a third transmission gear G3, a first clutch C1 and a second clutch C2. The first driving gear P1 and the second driving gear P2 are connected to the rotational resonance motor RM through the first transmission shaft T1. The first transmission gear G1 is connected with the actuator ED through the fourth transmission shaft T4. The second transmission gear G2 is connected with the first clutch C1 through the second transmission shaft T2. The third transmission gear G3 is connected with the second clutch C2 through the third transmission shaft T3. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transfer shaft T2 through the first clutch C1. The third driven gear W3 is connected to the third transmission shaft T3 through the second clutch C2. The fourth driven gear W4 is connected to the third transfer shaft T3 through the second clutch C2. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The third driven gear W3 is selectively engageable with and disengageable from the third transfer shaft T3 by the action of the second clutch C2. The fourth driven gear W4 is selectively engageable with and disengageable from the third transfer shaft T3 by the action of the second clutch C2. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. The first driving gear P1 and the third driven gear W3 are engaged with each other. The second driving gear P2 is meshed with the fourth driven gear W4. The first transmission gear G1 is meshed with the second transmission gear G2. The first transmission gear G1 is meshed with the third transmission gear G3. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED in four transmission ratios.

The transmission TM, as shown in fig. 14, includes: a first transmission shaft T1, a second transmission shaft T2, a third transmission shaft T3, a fourth transmission shaft T4, a first driving gear P1, a second driving gear P2, a third driving gear P3, a fourth driving gear P4, a first driven gear W1, a second driven gear W2, a third driven gear W3, a fourth driven gear W4, a fifth driven gear W5, a sixth driven gear W6, a seventh driven gear W7, an eighth driven gear W8, a first transmission gear G1, a second transmission gear G2, a third transmission gear G3, a first clutch C1, a second clutch C2, a third clutch C3, and a fourth clutch C4. The first driving gear P1, the second driving gear P2, the third driving gear P3 and the fourth driving gear P4 are connected to the rotational resonance motor RM through the first transmission shaft T1. The first transmission gear G1 is connected with the actuator ED through the fourth transmission shaft T4. The second transmission gear G2, the first clutch C1 and the second clutch C2 are all connected with the second transmission shaft T2. The third transmission gear G3, the third clutch C3 and the fourth clutch C4 are all connected with the third transmission shaft T3. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transmission shaft T2 through the second clutch C2. The third driven gear W3 is connected to the second transfer shaft T2 through the first clutch C1. The fourth driven gear W4 is connected to the second transfer shaft T2 through the second clutch C2. The fifth driven gear W5 is connected to the third transmission shaft T3 through the third clutch C3. The sixth driven gear W6 is connected to the third transmission shaft T3 through the fourth clutch C4. The seventh driven gear W7 is connected to the third transmission shaft T3 through the third clutch C3. The eighth driven gear W8 is connected to the third transmission shaft T3 through the fourth clutch C4. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The third driven gear W3 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The fourth driven gear W4 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The fifth driven gear W5 is selectively engageable with and disengageable from the third transfer shaft T3 by the third clutch C3. The sixth driven gear W6 is selectively engageable with and disengageable from the third transfer shaft T3 by the action of the fourth clutch C4. The seventh driven gear W7 is selectively engageable with and disengageable from the third transfer shaft T3 by the third clutch C3. The eighth driven gear W8 is selectively engageable with and disengageable from the third transfer shaft T3 by the action of the fourth clutch C4. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. The third driving gear P3 is engaged with the third driven gear W3. The fourth driving gear P4 is engaged with the fourth driven gear W4. The first driving gear P1 and the fifth driven gear W5 are engaged with each other. The second driving gear P2 is engaged with the eighth driven gear W8. The third driving gear P3 is engaged with the seventh driven gear W7. The fourth driving gear P4 is engaged with the sixth driven gear W6. The first transmission gear G1 is meshed with the second transmission gear G2. The first transmission gear G1 is meshed with the third transmission gear G3. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED in eight transmission ratios.

The transmission TM, as shown in fig. 15, includes: the transmission mechanism comprises a first transmission shaft T1, a second transmission shaft T2, a first driving gear P1, a second driving gear P2, a third driving gear P3, a fourth driving gear P4, a first driven gear W1, a second driven gear W2, a third driven gear W3, a fourth driven gear W4, a first clutch C1 and a second clutch C2. The first driving gear P1, the second driving gear P2, the third driving gear P3 and the fourth driving gear P4 are all connected to the rotational resonance motor RM through the first transmission shaft T1. The first clutch C1 and the second clutch C2 are connected with the actuator ED through the second transmission shaft T2. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transmission shaft T2 through the second clutch C2. The third driven gear W3 is connected to the second transfer shaft T2 through the first clutch C1. The fourth driven gear W4 is connected to the second transfer shaft T2 through the second clutch C2. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The third driven gear W3 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The fourth driven gear W4 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. The third driving gear P3 is engaged with the third driven gear W3. The fourth driving gear P4 is engaged with the fourth driven gear W4. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED in four transmission ratios.

The transmission TM, as shown in fig. 16, includes: the transmission mechanism comprises a first transmission shaft T1, a second transmission shaft T2, a third transmission shaft T3, a fourth transmission shaft T4, a first driving gear P1, a second driving gear P2, a third driving gear P3, a fourth driving gear P4, a first driven gear W1, a second driven gear W2, a third driven gear W3, a fourth driven gear W4, a fifth driven gear W5, a sixth driven gear W6, a first transmission gear G1, a second transmission gear G2, a third transmission gear G3, a first clutch C1, a second clutch C2 and a third clutch C3. The first driving gear P1, the second driving gear P2, the third driving gear P3 and the fourth driving gear P4 are connected to the rotational resonance motor RM through the first transmission shaft T1. The first transmission gear G1 is connected with the actuator ED through the fourth transmission shaft T4. The second transmission gear G2, the first clutch C1 and the second clutch C2 are all connected with the second transmission shaft T2. The third transmission gear G3 and the third clutch C3 are connected with the third transmission shaft T3. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transmission shaft T2 through the second clutch C2. The third driven gear W3 is connected to the second transfer shaft T2 through the first clutch C1. The fourth driven gear W4 is connected to the second transfer shaft T2 through the second clutch C2. The fifth driven gear W5 is connected to the third transmission shaft T3 through the third clutch C3. The sixth driven gear W6 is connected to the third transmission shaft T3 through the third clutch C3. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The third driven gear W3 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The fourth driven gear W4 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The fifth driven gear W5 is selectively engageable with and disengageable from the third transfer shaft T3 by the third clutch C3. The sixth driven gear W6 is selectively engageable with and disengageable from the third transfer shaft T3 by the third clutch C3. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. The third driving gear P3 is engaged with the third driven gear W3. The fourth driving gear P4 is engaged with the fourth driven gear W4. The first driving gear P1 and the fifth driven gear W5 are engaged with each other. The third driving gear P3 is engaged with the sixth driven gear W6. The first transmission gear G1 is meshed with the second transmission gear G2. The first transmission gear G1 is meshed with the third transmission gear G3. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED in six transmission ratios.

The transmission TM, as shown in fig. 17, includes: the clutch comprises a first transmission shaft T1, a second transmission shaft T2, a first driving gear P1, a second driving gear P2, a third driving gear P3, a fourth driving gear P4, a fifth driving gear P5, a sixth driving gear P6, a seventh driving gear P7, an eighth driving gear P8, a first driven gear W1, a second driven gear W2, a third driven gear W3, a fourth driven gear W4, a fifth driven gear W5, a sixth driven gear W6, a seventh driven gear W7, an eighth driven gear W8, a first clutch C1, a second clutch C2, a third clutch C3 and a fourth clutch C4. The first driving gear P1, the second driving gear P2, the third driving gear P3, the fourth driving gear P4, the fifth driving gear P5, the sixth driving gear P6, the seventh driving gear P7, and the eighth driving gear P8 are all connected to the rotational resonance motor RM through the first transmission shaft T1. The first clutch C1, the second clutch C2, the third clutch C3 and the fourth clutch C4 are all connected with the actuator ED through the second transmission shaft T2. The first driven gear W1 is connected to the second transfer shaft T2 through the first clutch C1. The second driven gear W2 is connected to the second transmission shaft T2 through the second clutch C2. The third driven gear W3 is connected to the second transfer shaft T2 through the first clutch C1. The fourth driven gear W4 is connected to the second transfer shaft T2 through the second clutch C2. The fifth driven gear W5 is connected to the second transmission shaft T2 through the third clutch C3. The sixth driven gear W6 is connected to the second transmission shaft T2 through the fourth clutch C4. The seventh driven gear W7 is connected to the second transmission shaft T2 through the third clutch C3. The eighth driven gear W8 is connected to the second transmission shaft T2 through the fourth clutch C4. The first driven gear W1 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The second driven gear W2 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The third driven gear W3 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the first clutch C1. The fourth driven gear W4 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the second clutch C2. The fifth driven gear W5 is selectively engageable with and disengageable from the second transfer shaft T2 by the third clutch C3. The sixth driven gear W6 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the fourth clutch C4. The seventh driven gear W7 is selectively engageable with and disengageable from the second transfer shaft T2 by the third clutch C3. The eighth driven gear W8 is selectively engageable with and disengageable from the second transfer shaft T2 by the action of the fourth clutch C4. The first driving gear P1 is engaged with the first driven gear W1. The second driving gear P2 is meshed with the second driven gear W2. The third driving gear P3 is engaged with the third driven gear W3. The fourth driving gear P4 is engaged with the fourth driven gear W4. The fifth driving gear P5 is engaged with the fifth driven gear W5. The sixth driving gear P6 is engaged with the sixth driven gear W6. The seventh driving gear P7 is engaged with the seventh driven gear W7. The eighth driving gear P8 is meshed with the eighth driven gear W8. Under the action of the transmission TM, the rotating resonance motor RM can selectively drive the actuator ED in eight transmission ratios.

Example 3

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 3, is similar in construction to embodiment 2 except that: in embodiment 3, the transmission TM may implement an automatic shift function under the action of the controller CS.

Example 4

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 4, is similar in construction to embodiment 1 except that: in embodiment 4, the vibration damping device DP is added; the vibration damping device DP has the function of reducing the vibration and noise transmitted by the device; and/or the vibration damping device DP; the function of reducing vibration by directly or indirectly utilizing the vibration damping characteristic of the spring vibrator system is provided; the rotational resonance motor RM is connected to the case EH through the vibration damping device DP; the vibration reduction damping device DP has a certain damping function on the vibration generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain buffering function on impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain vibration damping function on the impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain damping function on vibration and impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain attenuation function on the noise generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain function of eliminating or isolating vibration and impact generated in the operation process of the rotary resonance motor RM.

Example 5

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 5, is similar in construction to embodiment 2 except that: in example 5, the vibration damping device DP was added; the vibration damping device DP has the function of reducing the vibration and noise transmitted by the device; and/or the vibration damping device DP is configured to have at least a function of reducing vibration directly or indirectly by using a vibration damping characteristic of a spring oscillator system; the rotational resonance motor RM is connected to the case EH through the vibration damping device DP; the transmission device TM is connected with the housing EH through the vibration damping device DP; the vibration reduction damping device DP has a certain damping function on the vibration generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain buffering function on impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain vibration damping function on the impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain damping function on vibration and impact generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain attenuation function on the noise generated in the running process of the rotary resonance motor RM; and/or the vibration damping device DP has a certain elimination or isolation function on the vibration and impact generated in the running process of the rotary resonance motor RM; the vibration reduction damping device DP has a certain damping function on vibration generated in the running process of the transmission TM; and/or the vibration damping device DP has a certain buffering function on impact generated in the running process of the transmission TM; and/or the vibration damping device DP has a certain vibration damping function on the impact generated in the running process of the transmission TM; and/or the vibration damping device DP has a certain damping function on vibration and impact generated in the running process of the transmission device TM; and/or the vibration damping device DP has a certain attenuation function on the noise generated in the running process of the transmission TM; and/or the vibration damping device DP has a certain function of eliminating or isolating vibration and impact generated in the running process of the transmission device TM.

Example 6

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 6, is similar in construction to embodiment 5 except that: in embodiment 6, the transmission TM can perform an automatic shift function under the action of the controller CS.

Example 7

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 7, is similar in construction to embodiment 4 except that: in embodiment 7, a motor support FB is added; the vibration damping device DP is arranged on the motor bracket FB; the rotary resonance motor RM is arranged on the motor bracket FB; the vibration damping device DP is connected with the rotary resonance motor RM through the motor bracket FB; the rotary resonance motor RM is connected with the shell EH through the motor bracket FB; the rotational resonance motor RM may reduce the vibration conducted from the motor bracket FB to the case EH by using the vibration damping device DP; and/or the rotational resonance motor RM may reduce noise conducted from the motor mount FB to the housing EH by means of the vibration damping device DP; the vibration damping device DP may reduce the vibration of the rotational resonance motor RM transmitted to the case EH through the motor mount FB; and/or the vibration damping device DP may reduce noise conducted from the rotational resonance motor RM to the case EH through the motor mount FB; and/or the vibration damping device DP can absorb the vibration of the motor bracket FB by utilizing a self spring vibrator system; and/or the vibration damping device DP can absorb the vibration of the rotational resonance motor RM through the motor mount FB by using its own spring oscillator system.

Example 8

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 8, is similar in construction to embodiment 2 except that: in embodiment 8, a vibration damping device DP and a motor mount FB are added; the vibration damping device DP is arranged on the motor bracket FB; the rotary resonance motor RM is arranged on the motor bracket FB; the transmission device TM is arranged on the motor bracket FB; the vibration damping device DP is connected with the rotary resonance motor RM through the motor bracket FB; the rotary resonance motor RM is connected with the shell EH through the motor bracket FB; the transmission device TM is connected with the shell EH through the motor bracket FB; and/or the vibration damping device DP can absorb the vibration of the motor bracket FB by utilizing a self spring vibrator system; the rotational resonance motor RM may reduce the vibration conducted from the motor bracket FB to the case EH by using the vibration damping device DP; and/or the rotational resonance motor RM may reduce noise conducted from the motor mount FB to the housing EH by means of the vibration damping device DP; the vibration damping device DP may reduce the vibration of the rotational resonance motor RM transmitted to the case EH through the motor mount FB; and/or the vibration damping device DP may reduce noise conducted from the rotational resonance motor RM to the case EH through the motor mount FB; and/or the vibration damping device DP can absorb the vibration of the rotary resonance motor RM through the motor bracket FB by utilizing a self spring vibrator system; the transmission TM may reduce the vibration conducted from the motor mount FB to the housing EH using the vibration damping device DP; the transmission TM may reduce noise transmitted from the motor mount FB to the housing EH using the vibration damping device DP; and/or the vibration damping device DP may reduce the vibration of the transmission TM conducted to the housing EH through the motor mount FB; and/or the vibration damping device DP may reduce the noise conducted by the transmission TM to the housing EH through the motor mount FB; and/or the vibration damping device DP can absorb the vibration of the transmission TM by means of its own spring oscillator system via the motor mount FB.

Example 9

An electric toothbrush RMT having a rotary resonance motor, as shown in fig. 9, is similar in construction to embodiment 8 except that: in embodiment 9, the transmission TM can perform an automatic shift function under the action of the controller CS.

It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design alternative embodiments without departing from the scope of the appended claims. The present embodiments are therefore to be considered as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, and any reference signs in the claims are not intended to be construed as limiting the claim concerned. In the claims, the word "comprising" does not exclude the presence of data or steps not listed in a claim.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment includes only a single embodiment, and such description is for clarity only, and those skilled in the art should make the description as a whole, and the embodiments may be appropriately combined to form other embodiments understood by those skilled in the art.

Claims (10)

1. At least one electric toothbrush (RMT) with a rotating resonant motor, at least for direct or indirect cleaning and care of the teeth, and/or interdental spaces, and/or oral cavity, characterized in that:

the electric toothbrush (RMT) with a rotary resonance motor comprises at least —

A housing (EH);

the housing (EH) is configured at least as a base, and/or as a mounting, and/or as a connection, and/or as a support, and/or as a fixture, and/or as a peripheral envelope of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The housing (EH) is configured to at least function to connect, and/or mount, and/or locate, and/or support, and/or envelope other components; and/or

The housing (EH) is configured to have at least the function of being directly or indirectly fixable relative to a human hand, and/or an operating table, and/or a wall of a mounting room; and/or

The housing (EH) is configured at least as one or more functional modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The housing (EH) is configured at least as one or more mounting modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The housing (EH) is configured to function at least as a modular connection and assembly; and/or

The housing (EH) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with a rotary Resonance Motor (RMT) into a new functional module; and/or

The housing (EH) is configured to function at least as a new assembly module directly or indirectly in combination with other modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The housing (EH) comprises at least one or more devices; and/or

The housing (EH) comprises at least one or more parts, components or members;

an actuating device (ED) which is arranged in the housing (EH) and is directly or indirectly connected with the housing (EH); or

An actuating device (ED) which is arranged outside the housing (EH) and is directly or indirectly connected with the housing (EH); and/or

The actuating device (ED) is configured at least to have a function of cleaning or caring for teeth; and/or

The actuating device (ED) is configured at least to have the function of cleaning or caring for teeth directly or indirectly by means of a toothbrush; and/or

The actuating device (ED) is configured at least to have the function of cleaning or caring for the teeth directly or indirectly via the brush head; and/or

The actuating device (ED) is configured at least to have the function of cleaning or caring for interdental spaces; and/or

The actuating device (ED) is configured at least to function directly or indirectly through an interdental brush for cleaning or caring for interdental spaces; and/or

The actuating device (ED) is configured at least to function as a cleaning or care dental orthodontic retainer; and/or

The actuating device (ED) is configured to have at least the function of cleaning or caring for teeth directly or indirectly by means of an orthodontic brush; and/or

The actuating device (ED) is configured to at least function to clean or care an orthodontic retainer directly or indirectly by means of an orthodontic brush; and/or

The actuating device (ED) is configured at least to have the function of cleaning or caring for dentures; and/or

The actuator (ED) is configured to have at least a function of massaging the gums; and/or

The actuator (ED) is configured to have at least a function of massaging the oral cavity; and/or

Said actuating device (ED) is configured to have at least the function of driving the tooth-brushing head directly or indirectly by means of mechanical energy so as to effect a vibration, and/or oscillation, and/or rotation, and/or movement of the tooth-brushing head; and/or

Said actuating means (ED) being configured to have at least the function of driving the interdental brush head directly or indirectly by means of mechanical energy so as to effect a vibration, and/or a swinging, and/or a rotation, and/or a movement of the interdental brush head; and/or

Said actuating device (ED) is configured to have at least the function of driving the orthodontic brushhead directly or indirectly by means of mechanical energy, so as to effect a vibration, and/or a swinging, and/or a rotation, and/or a movement of the orthodontic brushhead; and/or

The actuating device (ED) is configured to have at least the function of driving the massage head directly or indirectly by means of mechanical energy so as to massage the gums; and/or

The actuator (ED) is configured to have at least the function of driving the massage heads directly or indirectly by means of mechanical energy so as to massage the oral cavity; and/or

Said actuator device (ED) is configured at least with the function of directly or indirectly transmitting the state of the teeth, and/or the interdental space, and/or the oral cavity to said electric toothbrush with rotating Resonance Motor (RMT); and/or

Said actuator device (ED) is configured at least with the function of directly or indirectly transmitting information of the teeth, and/or the slits between the teeth, and/or the oral cavity to said electric toothbrush with rotating Resonance Motor (RMT); and/or

Said actuating device (ED) is configured at least with the function of displaying the state of the teeth, and/or the slits between the teeth, and/or the mouth, directly or indirectly to the operator; and/or

The actuator (ED) is configured to have at least the function of directly or indirectly displaying information on the teeth, and/or slits between the teeth, and/or mouth to the operator; and/or

The Execution Device (ED) is configured to function at least as a wireless and/or wired network connection; and/or

The actuating device (ED) is configured at least to transmit and/or receive wireless signals; and/or

The actuation device (ED) is configured at least with the function of transmitting and/or receiving wired signals; and/or

The Execution Device (ED) is configured to have at least the function of directly or indirectly establishing a local area network; and/or

The Execution Device (ED) is configured at least with the function of directly or indirectly transferring data; and/or

The Execution Device (ED) is configured at least with the function of receiving data directly or indirectly; and/or

The Execution Device (ED) is configured at least with the function of sending data directly or indirectly; and/or

The Execution Device (ED) is configured at least with the function of directly or indirectly processing data; and/or

The Execution Device (ED) is configured to have at least the function of taking pictures directly or indirectly; and/or

The Execution Device (ED) is configured to at least function for directly or indirectly recording video; and/or

The Execution Device (ED) is configured to have at least the functions of picture display and processing; and/or

The Execution Device (ED) is configured to have at least video display and processing functions; and/or

The actuating device (ED) is configured at least with the function of directly or indirectly visualizing an operating process; and/or

The actuating device (ED) is configured at least with a selectively exchangeable function; and/or

Said actuating device (ED) is configured at least as one or more functional modules of said electric toothbrush with rotating Resonant Motor (RMT); and/or

Said actuating device (ED) is configured at least as one or more fitting modules of said electric toothbrush with rotating Resonant Motor (RMT); and/or

The actuating device (ED) is configured at least with modular connection and assembly functions; and/or

Said actuator device (ED) is configured at least with the function of combining directly or indirectly with the other modules of said electric toothbrush with rotating Resonant Motor (RMT) into a new functional module; and/or

Said actuator device (ED) is configured at least with the function of combining directly or indirectly with other modules of said electric toothbrush with rotating Resonant Motor (RMT) into a new assembly module; and/or

Said executing means (ED) comprise at least one or more means; and/or

Said actuating device (ED) comprising at least one or more parts, components or members;

a rotating resonance electric machine (RM) disposed within the housing (EH) and connected directly or indirectly to the housing (EH); and/or

The rotary Resonance Motor (RM) is configured at least as a power source of the electric toothbrush with rotary Resonance Motor (RMT); and/or

The rotational Resonance Motor (RM) is configured to have at least a function of being selectively vibrated in a rotational direction; and/or

The rotating Resonance Machine (RM) is directly or indirectly connected with Electric Power (EP); and/or

The Electric Power (EP) is an external power supply; and/or

The rotational Resonance Motor (RM) is configured to have at least a function of generating rotational vibration directly or indirectly using the Electric Power (EP); and/or

The rotational resonance electrical machine (RM) is configured to function at least as mechanical energy for generating rotational vibrations directly or indirectly from electrical energy of the Electrical Power (EP); and/or

Said rotary resonant electric machine (RM) being configured at least with the function of directly or indirectly converting said Electric Power (EP) into power for driving said electric toothbrush with rotary resonant electric machine (RMT); and/or

Said rotary Resonant Motor (RM) being configured at least with the function of directly or indirectly converting electrical energy into mechanical energy for driving said electric toothbrush with rotary Resonant Motor (RMT); and/or

The rotary Resonance Motor (RM) is configured to have at least a function of driving the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly using the Electric Power (EP); and/or

The rotary Resonance Motor (RM) is configured to have at least a selectively replaceable function; and/or

The rotary Resonance Motor (RM) is configured at least as one or more functional modules of the electric toothbrush with rotary Resonance Motor (RMT); and/or

The rotational Resonance Motor (RM) is configured at least as one or more mounting modules of the electric toothbrush with rotational Resonance Motor (RMT); and/or

The rotational Resonance Motor (RM) is configured to have at least a function of modular connection and assembly; and/or

The rotary Resonance Motor (RM) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with rotary Resonance Motor (RMT) into a new functional module; and/or

The rotary Resonant Motor (RM) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with rotary Resonant Motor (RMT) into a new assembly module; and/or

The rotating resonant electric machine (RM) comprises at least one or more devices; and/or

The rotary resonant electric machine (RM) comprises at least one or more parts, components or members; and/or

A Transmission (TM) disposed within the housing (EH) and directly or indirectly connected to the housing (EH); and/or

The Transmission (TM) is configured to have at least a function of transmitting power; and/or

The Transmission (TM) is configured to function at least as a transmission ratio; and/or

The Transmission (TM) is configured to function at least as a plurality of transmission ratios; and/or

Said Transmission (TM) being configured to at least selectively transmit power in a plurality of transmission ratios; and/or

The Transmission (TM) is configured to transmit power at least in a range of transmission ratios; and/or

Said Transmission (TM) being configured to at least selectively transmit power over a range of transmission ratios; and/or

The Transmission (TM) is configured to have at least a self-shifting function; and/or

The Transmission (TM) is configured to have at least a manual shifting function; and/or

The Transmission (TM) is configured to have at least an automatic gear shifting function; and/or

The Transmission (TM) is configured to have at least a selectively replaceable function; and/or

The Transmission (TM) is configured at least as one or more functional modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The Transmission (TM) is configured at least as one or more assembly modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The Transmission (TM) is configured to have at least a modular connection and assembly function; and/or

Said Transmission (TM) being configured at least to function as a new functional module directly or indirectly combined with the other modules of said electric toothbrush with rotating Resonant Motor (RMT); and/or

Said Transmission (TM) being configured at least to function as a new assembly module directly or indirectly combined with the other modules of said electric toothbrush with rotating Resonant Motor (RMT); and/or

Said Transmission Means (TM) comprise at least one or more devices; and/or

Said Transmission (TM) comprises at least one or more parts, components or members; and/or

A motor bracket (FB) disposed in the housing (EH) and directly or indirectly connected to the housing (EH); and/or

The motor support (FB) is at least configured as a base, and/or as a mounting, and/or as a connecting, and/or as a support, and/or as a fixing, and/or as an envelope of the rotary Resonance Motor (RM); and/or

Said motor support (FB) is configured to at least have the function of connecting, and/or mounting, and/or positioning, and/or supporting, and/or enveloping said rotational Resonance Motor (RM); and/or

Said motor support (FB) being configured at least to function as a connection, and/or mounting, and/or positioning, and/or supporting, and/or enveloping, said Transmission (TM); and/or

The motor support (FB) is configured at least as one or more functional modules of the electric toothbrush with rotating Resonance Motor (RMT); and/or

The motor support (FB) is configured at least as one or more mounting modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The motor support (FB) is configured to have at least a function of modular connection and assembly; and/or

The motor supporter (FB) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with a rotary Resonance Motor (RMT) into a new functional module; and/or

The motor support (FB) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with a rotary Resonance Motor (RMT) into a new assembly module; and/or

Said motor support (FB) comprising at least one or more devices; and/or

Said motor support (FB) comprising at least one or more parts, components or members; and/or

A Controller (CS) disposed within the housing (EH) and connected directly or indirectly to the housing (EH); or

A Controller (CS) disposed outside the housing (EH) and directly or indirectly connected to the housing (EH); and/or

The Controller (CS) is configured to have at least a function of selectively switching on and off the Electric Power (EP) directly or indirectly; and/or

The Controller (CS) is configured to have at least a function of selectively controlling the rotary Resonance Motor (RM) directly or indirectly; and/or

The Controller (CS) is configured to at least function to selectively control the Transmission (TM) directly or indirectly; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction directly or indirectly with a user of the electric toothbrush with a rotary Resonance Motor (RMT); and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through a button; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly through light; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through a display; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through mobile phone software; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly through a wireless network; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through Bluetooth; and/or

The Controller (CS) is configured at least with the function of enabling human-machine interaction with a user of the electric toothbrush with rotating Resonant Motor (RMT), directly or indirectly by infrared detection; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly through an audio signal; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through a microphone; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly through an image sensing signal; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with a rotary Resonance Motor (RMT) directly or indirectly through a remote control signal; and/or

The Controller (CS) is configured to have at least a function of realizing human-computer interaction with a user of the electric toothbrush with rotary Resonance Motor (RMT) directly or indirectly through a remote control panel; and/or

The Controller (CS) is configured to have at least a function of directly or indirectly setting an operation mode; and/or

The Controller (CS) is configured to have at least a function of directly or indirectly memorizing a common setting of a user of the electric toothbrush with a rotary Resonance Motor (RMT); and/or

The Controller (CS) is configured to have at least a function of directly or indirectly performing self-learning and optimization improvement; and/or

The Controller (CS) is configured to have at least a function of directly or indirectly memorizing a plurality of operation modes; and/or

The Controller (CS) is configured to have at least a function of directly or indirectly performing one-touch setting of a plurality of operation modes; and/or

The Controller (CS) is configured to have at least a selectively replaceable function; and/or

The Controller (CS) is configured at least as one or more functional modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The Controller (CS) is configured at least as one or more mounting modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The Controller (CS) is configured to have at least a function of modular connection and assembly; and/or

The Controller (CS) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with rotary Resonance Motor (RMT) into a new functional module; and/or

The Controller (CS) is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with rotary Resonance Motor (RMT) into a new assembly module; and/or

The Controller (CS) comprises at least one or more devices; and/or

The Controller (CS) comprises at least one or more parts, components or members; and/or

A battery (EB) disposed within the housing (EH) and connected directly or indirectly to the housing (EH); or

A battery (EB) disposed outside the housing (EH) and directly or indirectly connected to the housing (EH); and/or

The battery (EB) is configured to have at least the function of storing electrical energy directly or indirectly; and/or

The battery (EB) is directly or indirectly connected with the Controller (CS); and/or

The battery (EB) is configured to have at least a function of selectively charging and discharging under direct or indirect control of the Controller (CS); and/or

The battery (EB) is configured to have at least a function of selectively self-charging and discharging; and/or

Said battery (EB) is connected directly or indirectly to said Electric Power (EP); and/or

Under the direct or indirect action of the Controller (CS), the battery (EB) is configured to be at least provided with the function of charging with the Electric Power (EP); and/or

Said battery (EB) is connected directly or indirectly to said rotating resonance electric machine (RM); and/or

-said battery (EB) is configured to have at least the function of directly or indirectly supplying said rotating resonant electric machine (RM) with electric energy; and/or

The battery (EB) is configured to have at least the function of supplying the Controller (CS) with electric energy directly or indirectly; and/or

-said battery (EB) is configured to have at least the function of supplying electric energy, directly or indirectly, to said Transmission (TM); and/or

The battery (EB) is configured to have at least a function of directly or indirectly supplying electric power to the electric toothbrush with a rotating Resonance Motor (RMT); and/or

The battery (EB) is configured to have at least a selectively replaceable function; and/or

The battery (EB) is configured at least as one or more functional modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The battery (EB) is configured at least as one or more assembly modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The battery (EB) is configured to have at least the function of modular connection and assembly; and/or

The battery (EB) is configured to have at least the function of combining directly or indirectly with other modules of the electric toothbrush with rotating Resonant Motor (RMT) into a new functional module; and/or

The battery (EB) is configured to have at least the function of combining directly or indirectly with other modules of the electric toothbrush with rotating Resonant Motor (RMT) into a new assembled module; and/or

The battery (EB) comprises at least one or more devices; and/or

The battery (EB) comprises at least one or more parts, components or members; and/or

A detection device arranged in the housing (EH) and directly or indirectly connected with the housing (EH); or

A detection device arranged outside the housing (EH) and directly or indirectly connected with the housing (EH); and/or

Said detecting means being configured with at least the function of directly or indirectly measuring a physical quantity and converting said measured physical quantity into a corresponding information format, which is then transmitted or fed back to the Controller (CS), and/or to the electric toothbrush with rotating Resonant Motor (RMT), and/or to the user of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The detection means are configured at least for detecting directly or indirectly the vibration, and/or the impact, and/or the position, and/or the speed, and/or the acceleration, and/or the load sustained, and/or the torque transmitted, and/or the temperature of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The detection means are configured at least for directly or indirectly detecting the temperature, and/or the humidity, and/or the altitude, and/or the pressure, and/or the position, and/or the inclination angle of the environment in which the electric toothbrush with rotating Resonant Motor (RMT) is located; and/or

The detection means are configured at least for directly or indirectly detecting the magnitude of current, and/or the magnitude of voltage, and/or the magnitude of power of the Electric Power (EP); and/or

The detection means are configured at least for detecting directly or indirectly the deformation, and/or the load, and/or the temperature, and/or the vibration frequency, and/or the vibration amplitude, and/or the vibration direction, and/or the vibration angle, and/or the vibration phase of the housing (EH); and/or

The detection device is configured at least for directly or indirectly detecting a deformation, and/or a position, and/or an angle, and/or a load, and/or a temperature, and/or a vibration frequency, and/or a vibration amplitude, and/or a vibration direction, and/or a vibration angle, and/or a vibration phase of the motor support (FB); and/or

The detection device is configured at least for directly or indirectly detecting a vibration frequency, and/or a vibration amplitude, and/or a vibration phase, and/or a temperature, and/or a speed, and/or a position, and/or an angle, and/or a brightness, and/or a contrast, and/or a sharpness of the actuator device (ED); and/or

The detection device is configured at least for directly or indirectly detecting an input rotational speed, and/or an input torque, and/or an input current, and/or an input voltage, and/or an input power, and/or an output rotational speed, and/or an output torque, and/or an output current, and/or an output voltage, and/or an output power, and/or a vibration frequency, and/or a vibration amplitude, and/or a vibration direction, and/or a vibration angle, and/or a vibration phase of the rotating resonant electric machine (RM); and/or

The detection means are configured at least for directly or indirectly detecting the input power, and/or the input rotation speed, and/or the input torque, and/or the position, and/or the angle, and/or the output power, and/or the output rotation speed, and/or the output torque, and/or the vibration frequency, and/or the vibration amplitude, and/or the vibration direction, and/or the vibration angle, and/or the vibration phase of the Transmission (TM); and/or

The detection means are configured at least for directly or indirectly detecting the temperature of the Controller (CS), and/or fault information and fault status; and/or

The detection means are configured at least for detecting directly or indirectly the residual capacity, and/or the temperature, and/or the input current, and/or the input voltage, and/or the input power, and/or the output current, and/or the output voltage, and/or the output power, and/or fault information and fault status of the battery (EB); and/or

The battery (EB) is configured to at least function to directly or indirectly supply electrical energy to the detection device; and/or

The detection device is configured to have at least a selectively replaceable function; and/or

The detection device is at least configured as one or more functional modules of the electric toothbrush with rotating Resonance Motor (RMT); and/or

The detection device is at least configured as one or more fitting modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The detection device is at least configured to have the functions of modular connection and assembly; and/or

The detecting device is configured to have at least a function of combining directly or indirectly with other modules of the electric toothbrush with rotary Resonance Motor (RMT) into a new functional module; and/or

The detecting means is configured to function at least as a new assembly module directly or indirectly combined with other modules of the electric toothbrush with rotating Resonant Motor (RMT); and/or

The detection device at least comprises a detector or a sensor; and/or

The detection means comprises at least one or more parts, components or members; and/or

A vibration damping Device (DP) disposed within the housing (EH) and connected directly or indirectly to the housing (EH); or

A vibration damping Device (DP) disposed outside the housing (EH) and directly or indirectly connected to the housing (EH); and/or

The vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the vibration transmitted by itself; and/or

The vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise transmitted by itself; and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly utilizing the vibration damping characteristic of the spring oscillator system so as to directly or indirectly reduce the vibration of the connected parts; and/or

The vibration-damping Device (DP) is configured to have at least the function of reducing the vibrations transmitted by itself by directly or indirectly using the damping characteristics of the material; and/or

The vibration damping Device (DP) is configured to have at least the function of reducing the vibration transmitted by itself by directly or indirectly utilizing the structural damping characteristics; and/or

Said vibration damping Device (DP) being configured to be directly or indirectly connected with said rotary resonant electric machine (RM); and/or

The vibration damping Device (DP) is configured to be directly or indirectly connected with the Transmission (TM); and/or

The vibration damping Device (DP) is configured to be directly or indirectly connected with the motor bracket (FB); and/or

The vibration damping Device (DP) is configured to be directly or indirectly connected with the housing (EH); and/or

The rotary Resonance Motor (RM) is directly or indirectly connected with the motor bracket (FB) through the vibration damping Device (DP); and/or

The rotational Resonance Machine (RM) is connected to the housing (EH) directly or indirectly via the vibration-damping Device (DP); and/or

The transmission device (TM) is directly or indirectly connected with the motor bracket (FB) through the vibration damping Device (DP); and/or

The Transmission (TM) is connected to the housing (EH) directly or indirectly via the vibration-damping Device (DP); and/or

The motor support (FB) is directly or indirectly connected with the shell (EH) through the vibration damping Device (DP); and/or

The vibration damping Device (DP) is configured to have at least a certain damping function for the vibration generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to have at least a certain damping function for the impact generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to have at least a certain vibration damping function for the impact generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to at least have a certain damping function for vibration and impact generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to have at least a certain function of damping noise generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to at least have a function of eliminating or isolating certain vibration and impact generated during the operation of the rotary Resonance Motor (RM); and/or

The vibration damping Device (DP) is configured to have at least a certain damping function for the vibration generated during the operation of the transmission device (TM); and/or

The vibration damping Device (DP) is configured to have at least a certain buffering function for the impact generated in the operation process of the transmission device (TM); and/or

The vibration damping Device (DP) is configured to have at least a certain vibration damping function for the impact generated during the operation of the Transmission (TM); and/or

The vibration damping Device (DP) is configured to at least have a certain damping function for vibration and impact generated in the operation process of the transmission device (TM); and/or

The vibration damping Device (DP) is configured to at least provide a certain attenuation function to the noise generated during the operation of the Transmission (TM); and/or

The vibration damping Device (DP) is configured to at least have a certain function of eliminating or isolating vibration and impact generated in the operation process of the transmission device (TM); and/or

Said vibration damping Device (DP) being configured at least with a function of directly or indirectly reducing the vibrations of said rotary resonant electric machine (RM) transmitted to said electric machine support (FB); and/or

Said vibration damping Device (DP) being configured to have at least the function of directly or indirectly reducing the noise transmitted by said rotary resonant electric machine (RM) to said electric machine support (FB); and/or

The vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the vibration conducted by the rotary resonant electric machine (RM) to the housing (EH); and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing noise conducted from the rotary resonant electric machine (RM) to the housing (EH); and/or

The rotary resonant electric machine (RM) is configured to have at least a function of directly or indirectly reducing the vibration conducted from the motor mount (FB) to the case (EH) with the vibration damping Device (DP); and/or

The rotary resonant electric machine (RM) is configured to have at least a function of reducing noise conducted from the motor mount (FB) to the case (EH) directly or indirectly using the vibration damping Device (DP); and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the vibration of the rotary Resonance Motor (RM) transmitted to the housing (EH) through the motor mount (FB); and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing noise conducted from the rotary Resonance Motor (RM) to the case (EH) through the motor mount (FB); and/or

The vibration damping Device (DP) is configured to have at least the function of absorbing the vibration of the motor bracket (FB) directly or indirectly by using a spring vibrator system of the device; and/or

The vibration damping Device (DP) is configured to have at least a function of absorbing the vibration of the rotary Resonance Motor (RM) through the motor bracket (FB) directly or indirectly by using a spring vibrator system thereof; and/or

The vibration damping Device (DP) is configured to at least have the function of directly or indirectly reducing the vibration transmitted from the Transmission (TM) to the motor support (FB); and/or

The vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise transmitted from the Transmission (TM) to the motor support (FB); and/or

The vibration damping Device (DP) is configured to at least function to directly or indirectly reduce the vibration conducted from the Transmission (TM) to the housing (EH); and/or

The vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise conducted by the Transmission (TM) to the housing (EH); and/or

The Transmission (TM) is configured to have at least a function of reducing, directly or indirectly, the vibration conducted by the motor mount (FB) to the housing (EH) with the vibration damping Device (DP); and/or

The Transmission (TM) is configured to have at least a function of reducing, directly or indirectly, the noise conducted by the motor mount (FB) to the casing (EH) with the vibration damping Device (DP); and/or

The vibration damping Device (DP) is configured to at least have a function of directly or indirectly reducing the vibration of the Transmission (TM) transmitted to the housing (EH) through the motor mount (FB); and/or

The vibration damping Device (DP) is configured to at least have a function of directly or indirectly reducing noise transmitted from the Transmission (TM) to the housing (EH) through the motor mount (FB); and/or

The vibration-damping Device (DP) is configured to have at least the function of absorbing the vibration of the transmission device (TM) through the motor bracket (FB) directly or indirectly by using a spring oscillator system of the device; and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the vibration conducted from the motor mount (FB) to the housing (EH); and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing noise conducted from the motor mount (FB) to the housing (EH); and/or

The vibration-damping Device (DP) is configured to have at least the function of directly or indirectly reducing the hand-feel vibrations conducted by the housing (EH) to the user; and/or

The vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the ear noise conducted from the housing (EH) to the user; and/or

The vibration damping Device (DP) is configured to be directly or indirectly connected with the Controller (CS); and/or

The vibration damping Device (DP) is configured to be directly or indirectly connected with the detection device; and/or

The detection means are configured at least for directly or indirectly detecting the vibration frequency, and/or the vibration amplitude, and/or the vibration phase, and/or the temperature, and/or the velocity, and/or the position, and/or the angle of the vibration damping Device (DP); and/or

The vibration damping capacity or damping of the vibration damping Device (DP) is adjusted or set by the structure of the device; and/or

The vibration damping capacity or the damping magnitude of the vibration damping Device (DP) is directly or indirectly adjusted or controlled by the Controller (CS); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the vibration conducted from the rotary Resonance Motor (RM) to the motor bracket (FB); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the vibration conducted by the rotary resonant electric machine (RM) to the case (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to at least have the function of directly or indirectly reducing the vibration transmitted from the Transmission (TM) to the motor bracket (FB); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to at least function to directly or indirectly reduce the vibration conducted from the Transmission (TM) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the vibration conducted from the motor mount (FB) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping and damping Device (DP) is configured to at least have the function of directly or indirectly reducing the hand feeling vibration conducted from the housing (EH) to the user; and/or

Under the direct or indirect action of the Controller (CS) and/or the detection device, the vibration-damping Device (DP) is configured to at least have the function of directly or indirectly reducing the hand feeling vibrations conducted by the housing (EH) to the user; and/or

-under the direct or indirect action of said Controller (CS), and/or of said detection means, said vibration damping means (DP) are configured to have at least the function of directly or indirectly reducing the vibrations transmitted by said rotary resonant electric machine (RM) to said electric machine support (FB); and/or

-under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured to have at least the function of directly or indirectly reducing the vibrations transmitted by the rotating resonant electric machine (RM) to the casing (EH); and/or

Under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured at least to function directly or indirectly to reduce the vibrations transmitted by the Transmission (TM) to the motor support (FB); and/or

Under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured at least to function to reduce directly or indirectly the vibrations transmitted by the Transmission (TM) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), and/or the detection device, the vibration damping Device (DP) is configured to at least have a function of directly or indirectly reducing the vibration conducted from the motor mount (FB) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the noise conducted from the rotary Resonance Motor (RM) to the motor mount (FB); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the noise conducted by the rotary resonant electric machine (RM) to the case (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise transmitted from the Transmission (TM) to the motor bracket (FB); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise conducted by the Transmission (TM) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the noise conducted from the motor mount (FB) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), the vibration damping and damping Device (DP) is configured to have at least a function of directly or indirectly reducing the ear noise conducted from the housing (EH) to the user; and/or

-under the direct or indirect action of said Controller (CS), and/or of said detection means, said vibration damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise transmitted by said rotating resonant electric machine (RM) to said electric machine support (FB); and/or

-under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured to have at least the function of directly or indirectly reducing the noise transmitted by the rotating resonant electric machine (RM) to the casing (EH); and/or

Under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured at least to have the function of directly or indirectly reducing the noise transmitted by the Transmission (TM) to the motor support (FB); and/or

Under the direct or indirect action of the Controller (CS), and/or of the detection device, the vibration-damping Device (DP) is configured to at least function to reduce, directly or indirectly, the noise transmitted by the Transmission (TM) to the casing (EH); and/or

Under the direct or indirect action of the Controller (CS), and/or the detection device, the vibration damping Device (DP) is configured to have at least a function of directly or indirectly reducing the noise conducted from the motor mount (FB) to the housing (EH); and/or

Under the direct or indirect action of the Controller (CS), and/or the detection device, the vibration damping Device (DP) is configured to at least have a function of directly or indirectly reducing the ear noise conducted from the housing (EH) to the user; and/or

The detection device is configured at least for directly or indirectly detecting the vibration frequency, and/or the vibration intensity, and/or the vibration direction, and/or the vibration angle, and/or the vibration phase of the vibration damping Device (DP); and/or

The detection means are configured at least for detecting directly or indirectly the vibration frequency, and/or the vibration intensity, and/or the vibration direction, and/or the vibration angle, and/or the vibration phase of the electric toothbrush with a rotating Resonance Motor (RMT); and/or

-said battery (EB) is configured to have at least the function of supplying electrical energy, directly or indirectly, to said vibration damping Device (DP); and/or

The vibration damping Device (DP) is configured to have at least a selectively replaceable function; and/or

Said vibration damping Device (DP) is configured at least as one or more functional modules of said electric toothbrush with rotating resonant electric machine (RMT); and/or

Said vibration damping Device (DP) being configured at least as one or more assembly modules of said electric toothbrush with rotating resonant electric machine (RMT); and/or

The vibration damping Device (DP) is configured to have at least a modular connection and assembly function; and/or

Said vibration damping Device (DP) being configured at least with the function of combining directly or indirectly with other modules of said electric toothbrush with rotating resonant electric machine (RMT) into a new functional module; and/or

Said vibration damping Device (DP) being configured at least to function as a new assembly module directly or indirectly in combination with the other modules of said electric toothbrush with rotating resonant electric machine (RMT); and/or

Said vibration damping Device (DP) comprising at least one or more devices; and/or

Said vibration damping Device (DP) comprising at least one or more parts, components or members; and/or

The rotary Resonance Motor (RM) is provided with at least a vibrator and a stator; and/or

The vibrator is directly or indirectly connected with the Execution Device (ED); and/or

The vibrator is directly or indirectly connected with the transmission device (TM); and/or

The stator is directly or indirectly fixedly connected with the housing (EH); and/or

The stator is directly or indirectly fixedly connected with the motor bracket (FB); and/or

Said stator being directly or indirectly connected to said Electric Power (EP); and/or

Said stator being directly or indirectly connected to said battery (EB); and/or

The stator is directly or indirectly connected with the Controller (CS); and/or

The vibrator is directly or indirectly connected with the shell (EH) through a spring; and/or

The vibrator is directly or indirectly connected with the motor bracket (FB) through a spring; and/or

The stator is fixedly connected with the shell (EH) directly or indirectly through the vibration damping Device (DP); and/or

The stator is fixedly connected with the motor bracket (FB) directly or indirectly through the vibration damping Device (DP); and/or

A certain gap is formed between the stator and the vibrator; and/or

The stator is configured to have at least a function of selectively applying an electromagnetic force to the vibrator; and/or

Under the direct or indirect action of the stator, the vibrator and the spring form a system which is at least provided with the function of rotating resonance behavior near a certain frequency or in a certain frequency range; and/or

The actuating device (ED) is configured at least with the function of cleaning or caring for the teeth directly or indirectly by means of the power provided by the rotating Resonant Motor (RM); and/or

The actuator (ED) is configured to have at least the function of cleaning or caring for interdental spaces directly or indirectly by means of the power provided by the rotating resonant electric machine (RM); and/or

Said actuating device (ED) is configured to have at least the function of cleaning or caring an orthodontic retainer directly or indirectly by means of the power provided by said rotary resonant electric motor (RM); and/or

Said actuating device (ED) is configured at least with the function of cleaning or caring for the false teeth directly or indirectly by means of the power provided by said rotary resonant electric machine (RM); and/or

Said actuator means (ED) being configured at least to have the function of massaging the gums directly or indirectly by means of the power provided by said rotary Resonant Motor (RM); and/or

Said actuator means (ED) being configured at least to function as a massage oral cavity directly or indirectly by means of the power provided by said rotary resonant electric motor (RM); and/or

The actuating device (ED) is configured to have at least the function of cleaning or caring teeth through a brush head directly or indirectly by means of the power provided by the rotary Resonance Motor (RM); and/or

The actuator (ED) is configured to have at least a function of cleaning or caring for interdental spaces by an interdental brush directly or indirectly using power supplied from the rotary Resonance Motor (RM); and/or

The actuation device (ED) is configured to have at least the function of cleaning or caring an orthodontic retainer by an orthodontic brush directly or indirectly using the power provided by the rotary Resonant Motor (RM); and/or

The actuator (ED) is configured to have at least the function of cleaning or caring for dentures by means of a brush head, directly or indirectly using the power provided by the rotary Resonant Motor (RM); and/or

The actuator (ED) is configured to have at least a function of massaging the gums by a massage head directly or indirectly using the power provided by the rotary Resonance Motor (RM); and/or

The actuator (ED) is configured to have at least the function of massaging the oral cavity by means of a massaging head, directly or indirectly using the power provided by the rotary Resonance Motor (RM); and/or

Said actuating means (ED) being configured at least with the function of directly or indirectly using the power provided by said rotary Resonant Motor (RM) in order to effect the vibration, and/or oscillation, and/or rotation, and/or movement of the dental brush head; and/or

Said actuating means (ED) being configured at least to function directly or indirectly by means of the power provided by said rotating Resonant Motor (RM) so as to effect the oscillation, and/or the rotation, and/or the movement of the interdental head; and/or

Said actuating device (ED) is configured to have at least the function of directly or indirectly using the power provided by said rotary Resonant Motor (RM) to effect the vibration, and/or oscillation, and/or rotation, and/or movement of the orthodontic brushhead; and/or

The actuating device (ED) is configured to have at least the function of directly or indirectly utilizing the power provided by the rotary Resonance Motor (RM) so as to drive the massage head to massage the gum; and/or

The actuating device (ED) is configured to have at least the function of directly or indirectly utilizing the power provided by the rotary Resonance Motor (RM) so as to drive the massage head to massage the oral cavity; and/or

The actuating device (ED) is configured to perform at least the function of cleaning or caring for the teeth directly or indirectly by means of the power provided by the Transmission (TM); and/or

The actuator (ED) is configured to perform at least the function of cleaning or caring for interdental spaces directly or indirectly by means of the power provided by the Transmission (TM); and/or

Said actuating means (ED) being configured to at least function to clean or care for orthodontic retainers directly or indirectly by means of the power provided by said Transmission Means (TM); and/or

The actuator (ED) is configured to have at least the function of cleaning or caring for dentures directly or indirectly by means of the power provided by the Transmission (TM); and/or

Said actuator means (ED) being configured at least to function as a massaging means for massaging the gums directly or indirectly by means of the power provided by said Transmission Means (TM); and/or

Said actuator means (ED) being configured at least to function as a massage oral cavity directly or indirectly by means of the power provided by said Transmission Means (TM); and/or

The actuating device (ED) is configured to at least function to clean or care for teeth via a brush head directly or indirectly using the power provided by the transmission device (TM); and/or

The actuator (ED) is configured to at least function to clean or care for interdental spaces by means of an interdental brush directly or indirectly using power provided by the Transmission (TM); and/or

The actuation device (ED) is configured to have at least the function of cleaning or caring an orthodontic retainer by an orthodontic brush directly or indirectly using the power provided by the transmission device (TM); and/or

The actuator (ED) is configured to at least have the function of cleaning or caring for dentures by means of a brush head, directly or indirectly using the power provided by the Transmission (TM); and/or

The actuator (ED) is configured to have at least the function of massaging the gums by means of a massaging head, directly or indirectly using the power provided by the Transmission (TM); and/or

The actuator (ED) is configured to have at least the function of massaging the oral cavity by means of the massaging heads directly or indirectly using the power provided by the Transmission (TM); and/or

Said actuating means (ED) being configured at least to function directly or indirectly by means of the power provided by said Transmission Means (TM) so as to effect a vibration, and/or a swinging, and/or a rotation, and/or a movement of the tooth brush head; and/or

The actuator (ED) is configured to have at least the function of directly or indirectly using the power provided by the Transmission (TM) to effect vibration, and/or oscillation, and/or rotation, and/or movement of the interdental brush head; and/or

Said actuating means (ED) being configured at least to function directly or indirectly by means of the power provided by said Transmission Means (TM) to effect the oscillation, and/or rotation, and/or movement of the orthodontic brushhead; and/or

The Executing Device (ED) is at least provided with the function of directly or indirectly utilizing the power provided by the transmission device (TM) so as to drive the massage head to massage the gum; and/or

The Executing Device (ED) is at least provided with the function of directly or indirectly utilizing the power provided by the transmission device (TM) so as to drive the massage head to massage the oral cavity; and/or

The rotational resonance electric machine (RM) is configured to have at least a function of directly or indirectly transmitting power by means of the Transmission (TM); and/or

The rotational resonance electric machine (RM) is configured to have at least a function of directly or indirectly transmitting power within a range of transmission speed ratios by means of the Transmission (TM); and/or

Said rotating resonance electric machine (RM) being configured at least to transmit power, directly or indirectly, with said Transmission (TM) at a fixed transmission ratio; and/or

Said rotary resonant electric machine (RM) being configured at least with the function of selectively transmitting power in a plurality of fixed transmission ratios, directly or indirectly by means of said Transmission (TM); and/or

-said rotating resonant electric machine (RM) is configured at least with the function of reducing, directly or indirectly, the vibrations, shocks or noises generated during the operation of said rotating resonant electric machine (RM) by means of said vibration-damping means (DP); and/or

-said Transmission (TM) is configured at least to reduce, directly or indirectly, vibrations, shocks or noise generated during operation of said Transmission (TM) by means of said vibration-damping Device (DP); and/or

The actuator (ED) is configured to reduce, directly or indirectly, vibrations, shocks or noises generated during operation of the actuator (ED) by means of the vibration-damping Device (DP); and/or

The Controller (CS) is configured to perform at least a three-dimensional modeling function directly or indirectly based on input information of the actuator (ED); and/or

The Controller (CS) is configured to perform at least a three-dimensional modeling function directly or indirectly based on input information of the detection means; and/or

The rotational Resonance Motor (RM) is configured to have at least a function of directly or indirectly driving the Transmission (TM); and/or

The rotational Resonance Motor (RM) is configured to be directly or indirectly connected with the Transmission (TM); and/or

The rotational Resonance Motor (RM) is configured to be directly or indirectly connected with the actuator (ED); and/or

The rotary resonant electric machine (RM) is configured to be connected directly or indirectly via the Transmission (TM) with the actuator (ED); and/or

The rotary resonant electric machine (RM) is configured to have at least the function of selectively driving the actuator (ED) directly or indirectly within a range of transmission ratios; and/or

Said rotating Resonance Machine (RM) being configured at least to selectively drive said actuating device (ED) directly or indirectly in a transmission ratio; and/or

Said rotating resonance electric machine (RM) being configured at least to selectively drive, directly or indirectly, said actuating device (ED) in a plurality of transmission ratios; and/or

Under the direct or indirect action of the Transmission (TM), the rotating resonance electric machine (RM) is configured to have at least the function of selectively driving the actuator (ED) within a range of transmission ratios; and/or

Under the direct or indirect action of the Transmission (TM), the rotating resonance electric machine (RM) is configured to have at least the function of selectively driving the actuator (ED) in a transmission ratio; and/or

Under the direct or indirect action of the Transmission (TM), the rotating resonance electric machine (RM) is configured to have at least the function of selectively driving the actuator (ED) in a plurality of transmission ratios; and/or

The rotational Resonance Motor (RM) is configured to be directly or indirectly connected with the actuator (ED); and/or

The Controller (CS) is configured to be directly or indirectly connected with the rotary resonant electric machine (RM); and/or

The Controller (CS) is configured to be directly or indirectly connected with the Transmission (TM); and/or

The Controller (CS) is configured to be directly or indirectly connected with the actuator (ED); and/or

The detection means are configured to be directly or indirectly connected with the Controller (CS); and/or

The detection device is configured to be directly or indirectly connected with the battery (EB); and/or

Said detecting means being configured to be directly or indirectly connected to said rotating Resonance Motor (RM); and/or

The detection means are configured to be directly or indirectly connected with the Transmission Means (TM); and/or

The detection device is configured to be directly or indirectly connected to the actuator device (ED); and/or

The detection device is configured to be directly or indirectly connected with the vibration damping Device (DP); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring teeth; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring teeth directly or indirectly through a toothbrush; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for interdental spaces; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for interdental spaces directly or indirectly through an interdental brush; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to at least have a function of cleaning or caring an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to at least function to clean or care an orthodontic retainer; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to at least have a function of cleaning or caring for teeth directly or indirectly through an orthodontic brush; and/or

The electric toothbrush with a rotary Resonant Motor (RMT) is configured to at least function to clean or care an orthodontic retainer directly or indirectly through an orthodontic brush; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for a dental prosthesis; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly massaging gums; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly massaging the oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of driving a tooth brush head directly or indirectly by mechanical energy to realize vibration, and/or oscillation, and/or rotation, and/or movement of the tooth brush head to clean or care teeth; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of driving an interdental brush head directly or indirectly by mechanical energy to thereby perform vibration, and/or oscillation, and/or rotation, and/or movement of the interdental brush head to thereby clean or care interdental spaces; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly driving an orthodontic brushhead through mechanical energy to realize vibration, and/or oscillation, and/or rotation, and/or movement of the orthodontic brushhead to clean or care teeth and an orthodontic retainer of the teeth; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of driving a massage head directly or indirectly by mechanical energy to massage gums; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of driving a massage head directly or indirectly by mechanical energy to massage an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly displaying a state of teeth, and/or slits between teeth, and/or an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly processing information of teeth, and/or slits between teeth, and/or an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly displaying a state of teeth, and/or slits between teeth, and/or an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly processing information of teeth, and/or slits between teeth, and/or an oral cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to function at least as a wireless and/or wired network connection; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of transmitting and/or receiving a wireless signal; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of transmitting and/or receiving a wired signal; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly establishing a local area network; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly transferring data; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly receiving data; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly transmitting data; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to at least function to directly or indirectly process data; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly taking a picture; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly recording a video; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a picture display and processing function; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least video display and processing functions; and/or

The electric toothbrush with a rotating Resonance Motor (RMT) is configured with at least a function of directly or indirectly visualizing an operation process; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly realizing human-computer interaction; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of inputting information directly or indirectly through a key; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of setting directly or indirectly by a button; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of selecting an operation mode directly or indirectly by a button; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of displaying information directly or indirectly through an indicator lamp; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of displaying information directly or indirectly through a display screen or a touch screen; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of inputting information directly or indirectly through a display screen or a touch screen; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of setting an operation mode directly or indirectly through a display screen or a touch screen; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is constructed to have at least functions of directly or indirectly taking pictures and recording videos in real time deep into the oral cavity; and/or

The electric toothbrush with rotary Resonance Motor (RMT) is constructed to have at least functions of taking pictures and recording videos in real time directly or indirectly deeply into the nasal cavity; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is constructed to have at least functions of directly or indirectly penetrating into an ear cavity for photographing and real-time video recording; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly deep oral cavity for evaluation, and/or advice, and/or diagnosis; and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly deep nasal cavity for evaluation, and/or advice, and/or diagnosis; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly penetrating into an ear cavity for evaluation, and/or recommendation, and/or diagnosis; and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least a function of realizing interaction and manipulation directly or indirectly through a hand piece of an operator; and/or

The electric toothbrush with rotating Resonance Motor (RMT) is configured to have at least a function of realizing visualization directly or indirectly through a hand set of an operator; and/or

The electric toothbrush with a rotational Resonance Motor (RMT) is configured to have at least a function of realizing visualization directly or indirectly through an external display; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of realizing a virtual display directly or indirectly through a hand set of an operator; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of realizing virtual display directly or indirectly through an external display; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly reducing hand feeling vibration; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of directly or indirectly reducing an ear-feeling noise.

2. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotating Resonance Machine (RM) and the actuator (ED), the Transmission (TM) is configured to function as at least one transmission ratio; and/or

Between the rotary resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio that varies over a range of ratios.

3. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least two transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is provided with at least a first overrunning clutch (FC1), a second overrunning clutch (FC 2); and/or

The rotational resonance electric machine (RM) is connected to the actuator (ED) directly or indirectly via the first overrunning clutch (FC1) and the second overrunning clutch (FC 2); and/or

When the rotating Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2) and the transmission device (TM), the rotating Resonance Motor (RM) and the Execution Device (ED) have two transmission speed ratios; and/or

The Transmission (TM) is equipped with at least a first clutch (C1); and/or

The rotating Resonance Machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1); and/or

Under the direct or indirect action of the first clutch (C1) and the Transmission (TM), there are two transmission speed ratios between the rotary resonant electric machine (RM) and the actuator (ED).

4. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotary resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least three transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2) and a first clutch (C1); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1) and the transmission device (TM), the rotary Resonance Motor (RM) and the actuating device (ED) have three transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2) and the transmission device (TM), the rotary Resonance Motor (RM) and the actuator (ED) have three transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2); and/or

The rotary resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2); and/or

Under the direct or indirect action of the first clutch (C1), the second clutch (C2) and the Transmission (TM), there are three transmission speed ratios between the rotary resonant electric machine (RM) and the actuator (ED).

5. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotary resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least four transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2) and a first clutch (C1); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1) and the transmission device (TM), the rotary Resonance Motor (RM) and the actuating device (ED) have four transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2) and the transmission device (TM), the rotary Resonance Motor (RM) and the actuator (ED) have four transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2); and/or

The rotary resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2); and/or

Under the direct or indirect action of the first clutch (C1), the second clutch (C2) and the Transmission (TM), there are four transmission speed ratios between the rotary resonant electric machine (RM) and the actuator (ED).

6. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotating Resonance Machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least five transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2), a first clutch (C1) and a second clutch (C2); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2) and the transmission device (TM), the rotary Resonance Motor (RM) and the Execution Device (ED) have five transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2), a third clutch (C3); and/or

The rotational resonance electrical machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2), the third clutch (C3); and/or

Under the direct or indirect action of the first clutch (C1), the second clutch (C2), the third clutch (C3) and the Transmission (TM), there are five transmission speed ratios between the rotary resonance electric machine (RM) and the actuator (ED).

7. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

between the rotating Resonance Machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least six transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2), a first clutch (C1) and a second clutch (C2); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2) and the transmission device (TM), the rotary Resonance Motor (RM) and the Execution Device (ED) have six transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2), a third clutch (C3); and/or

The rotational resonance electrical machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2), the third clutch (C3); and/or

Under the direct or indirect action of the first clutch (C1), the second clutch (C2), the third clutch (C3) and the Transmission (TM), there are six transmission speed ratios between the rotary resonance electric machine (RM) and the actuator (ED).

8. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least seven transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2), a first clutch (C1), a second clutch (C2) and a third clutch (C3); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2), the third clutch (C3); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2), the third clutch (C3) and the transmission device (TM), the rotary Resonance Motor (RM) and the Execution Device (ED) have seven transmission speed ratios; and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2), the third clutch (C3), a fourth clutch (C4); and/or

The rotational resonance electrical machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2), the third clutch (C3), the fourth clutch (C4); and/or

Seven transmission ratios between the rotary resonant electric machine (RM) and the actuator (ED) under the direct or indirect action of the first clutch (C1), the second clutch (C2), the third clutch (C3), the fourth clutch (C4) and the Transmission (TM).

9. An electric toothbrush (RMT) with a rotating resonant motor according to claim 1, characterized in that:

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function with at least eight transmission ratios; and/or

-between the rotating resonant electric machine (RM) and the actuator (ED), the Transmission (TM) is configured to function at least as a transmission ratio variable within a range of ratios; and/or

The Transmission (TM) is at least provided with a first overrunning clutch (FC1), a second overrunning clutch (FC2), a first clutch (C1), a second clutch (C2) and a third clutch (C3); and/or

The rotational resonance electric machine (RM) is connected with the actuator (ED) directly or indirectly through the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2), the third clutch (C3); and/or

When the rotary Resonance Motor (RM) rotates forwards and reversely, eight transmission speed ratios are formed between the rotary Resonance Motor (RM) and the Executing Device (ED) under the direct or indirect action of the first overrunning clutch (FC1), the second overrunning clutch (FC2), the first clutch (C1), the second clutch (C2), the third clutch (C3) and the transmission device (TM); and/or

The Transmission (TM) is provided with at least the first clutch (C1), the second clutch (C2), the third clutch (C3), a fourth clutch (C4); and/or

The rotational resonance electrical machine (RM) is connected with the actuator (ED) directly or indirectly through the first clutch (C1), the second clutch (C2), the third clutch (C3), the fourth clutch (C4); and/or

Eight transmission ratios between the rotary resonant electric machine (RM) and the actuator (ED) under the direct or indirect action of the first clutch (C1), the second clutch (C2), the third clutch (C3), the fourth clutch (C4) and the Transmission (TM).

10. An electric toothbrush (RMT) with a rotating resonant motor according to any of claims 1 to 9, characterized in that:

under the direct or indirect action of the Transmission (TM), the actuation device (ED) is configured at least to function for cleaning or caring for the teeth by means of a toothbrush; and/or

Under the direct or indirect action of the Transmission (TM), the actuator (ED) is configured to at least perform the function of cleaning or caring the interdental space through an interdental brush; and/or

Under the direct or indirect action of the Transmission (TM), the actuation device (ED) is configured at least to perform the function of cleaning or caring teeth through an orthodontic brush; and/or

Under the direct or indirect action of the Transmission Means (TM), the actuation means (ED) are configured to perform at least the function of cleaning or caring orthodontic retainers by means of orthodontic brushes; and/or

Under the direct or indirect action of the transmission device (TM), the actuation device (ED) is configured to have at least the function of massaging the gums through a massage head; and/or

Under the direct or indirect action of the Transmission Means (TM), the actuation means (ED) are configured at least to have the function of massaging the oral cavity by means of massage heads; and/or

Under the direct or indirect action of the transmission device (TM), the actuating device (ED) is configured to drive at least the function of vibrating, and/or oscillating, and/or rotating, and/or moving the tooth brush head through mechanical energy; and/or

Under the direct or indirect action of the transmission device (TM), the actuating device (ED) is configured to drive at least the function of the interdental brush head to vibrate, and/or oscillate, and/or rotate, and/or move by mechanical energy; and/or

Under the direct or indirect action of the Transmission Means (TM), the actuating means (ED) are configured to have at least the function of driving the orthodontic brushhead to vibrate, and/or oscillate, and/or rotate, and/or move by mechanical energy; and/or

Under the direct or indirect action of the Transmission Means (TM), the actuation means (ED) are configured to have at least the function of driving the massage head to vibrate, and/or oscillate, and/or rotate, and/or move by mechanical energy; and/or

Under the direct or indirect action of the transmission device (TM), the actuating device (ED) is configured to at least have the function of driving the tooth brush head to clean or care teeth through mechanical energy; and/or

Under the direct or indirect action of the transmission device (TM), the actuating device (ED) is configured to at least have the function of driving the interdental brush head to clean or care interdental spaces through mechanical energy; and/or

Under the direct or indirect action of the Transmission Means (TM), the actuation means (ED) are configured to perform at least the function of driving an orthodontic brush head by mechanical energy to clean or care an orthodontic retainer; and/or

Under the direct or indirect action of the transmission device (TM), the Execution Device (ED) is configured to at least have the function of driving the massage head to massage the gum through mechanical energy; and/or

Under the direct or indirect action of the transmission device (TM), the actuating device (ED) is configured to at least have the function of driving the massage head to massage the oral cavity through mechanical energy; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for teeth directly or indirectly using the performing device (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for interdental spaces directly or indirectly using the actuator (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to at least have a function of cleaning or caring for an oral cavity directly or indirectly using the performing device (ED); and/or

The electric toothbrush with rotary Resonant Motor (RMT) is configured to at least function to clean or care orthodontic retainers directly or indirectly with the performing device (ED); and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for dentures directly or indirectly using the Execution Device (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of massaging gums directly or indirectly with the actuator (ED); and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least a function of massaging the oral cavity directly or indirectly with the actuator (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring teeth directly or indirectly using a toothbrush or a brushhead; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for interdental spaces directly or indirectly using an interdental brush; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring an oral cavity directly or indirectly using a toothbrush or a brushhead; and/or

The electric toothbrush with a rotary Resonant Motor (RMT) is configured to at least function to clean or care an orthodontic retainer directly or indirectly with an orthodontic brush; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of cleaning or caring for dentures directly or indirectly using a toothbrush or a brushhead; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of massaging gums directly or indirectly using a massage head; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of massaging the oral cavity directly or indirectly with a massage head; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of displaying a state of teeth, and/or slits of teeth, and/or oral cavity directly or indirectly using the actuator (ED); and/or

The electric toothbrush with rotating Resonance Motor (RMT) is configured to have at least a function of processing information of teeth, and/or slits of teeth, and/or oral cavity directly or indirectly by using the actuator (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of displaying a state of teeth, and/or slits of teeth, and/or oral cavity directly or indirectly using the actuator (ED); and/or

The electric toothbrush with rotating Resonance Motor (RMT) is configured to have at least a function of processing information of teeth, and/or slits of teeth, and/or oral cavity directly or indirectly by using the actuator (ED); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of reducing hand feeling vibration directly or indirectly by the vibration damping Device (DP); and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of reducing an ear-feeling noise directly or indirectly by the vibration damping Device (DP); and/or

Said electric toothbrush with rotating Resonant Motor (RMT) is configured to have at least one electric toothbrush operating mode in which said actuator (ED) can be selectively vibrated, and/or oscillated, and/or rotated, and/or moved, and/or said dental brushhead can be selectively vibrated, and/or oscillated, and/or rotated, and/or moved, so that said electric toothbrush with rotating Resonant Motor (RMT) can clean teeth under the manipulation of said user, and/or said user can selectively adjust at least the intensity, and/or the frequency with which said actuator (ED) cleans teeth within a certain range; and/or

Said electric toothbrush with rotating Resonant Motor (RMT) is configured to have at least one electric interdental brush operation mode in which said actuator (ED) can selectively vibrate, and/or oscillate, and/or rotate, and/or move, and/or said interdental brush can selectively vibrate, and/or oscillate, and/or rotate, and/or move, so that said electric toothbrush with rotating Resonant Motor (RMT) can clean interdental spaces under the manipulation of said user, and/or said user can selectively adjust at least the intensity, and/or the frequency of cleaning interdental spaces within a certain range; and/or

Said electric toothbrush with rotating Resonant Motor (RMT) is configured with at least one electric orthodontic brush operating mode in which said actuator means (ED) can selectively vibrate, and/or oscillate, and/or rotate, and/or move, and/or said orthodontic brush can selectively vibrate, and/or oscillate, and/or rotate, and/or move, so that said electric toothbrush with rotating Resonant Motor (RMT) can clean teeth and/or dental appliances under the manipulation of said user, and/or said user can selectively adjust at least the intensity, and/or the frequency of cleaning teeth and/or dental appliances within a certain range; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least one gum care operation mode in which the Execution Device (ED) can selectively massage the gums, and/or the massage head can selectively massage the gums, so that the electric toothbrush with a rotary Resonance Motor (RMT) can massage or care the gums under the manipulation of the user, and/or the user can selectively adjust at least the massage frequency, and/or the massage intensity of the massage head within a certain range; and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least one oral care operation mode in which the actuator (ED) can selectively massage the oral cavity and/or the massage head can selectively massage the oral cavity, so that the electric toothbrush with rotary Resonance Motor (RMT) can massage or care the oral cavity under the manipulation of the user, and/or the user can selectively adjust at least the massage frequency and/or the massage intensity of the actuator (ED) within a certain range and/or the user can selectively adjust at least the massage frequency and/or the massage intensity of the massage head within a certain range; and/or

The electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least one three-dimensional scanning and modeling operation mode in which the actuator (ED) can selectively perform three-dimensional scanning of teeth, slits of teeth, and gums and create corresponding three-dimensional models under the direct or indirect action of the Controller (CS), and three-dimensional scanning data and three-dimensional model data can be stored, transmitted, and edited; and/or

The electric toothbrush with rotating Resonance Motor (RMT) is configured to have at least one visual working mode, in which the actuator (ED) can selectively display the target object in real time, and/or enlarge, and/or reduce, and/or virtually display, and/or capture, and/or record, and the related data can be stored, transmitted, and edited under the direct or indirect action of the Controller (CS); and/or

The electric toothbrush with rotating Resonance Motor (RMT) is configured with at least one endoscopic working mode, in which the actuator (ED) can selectively enlarge and display the oral cavity and/or pores under the direct or indirect action of the Controller (CS), and can display, and/or capture and/or record real-time images and/or pictures, and the related data can be stored, transmitted and edited; and/or

The electric toothbrush with a rotating Resonance Motor (RMT) is configured to have at least one human-machine interaction operation mode in which the Controller (CS) can selectively give operation prompt information according to the user's input, and/or the feedback of the actuator (ED), and/or the feedback of the detector, and/or the feedback of the housing (EH), and/or the feedback of the rotating Resonance Motor (RM), and/or the feedback of the motor bracket (FB), and/or the feedback of the damping Device (DP), and/or the feedback of the Transmission (TM), and/or the self-feedback of the Controller (CS), and/or the feedback of the battery (EB), and/or the feedback of the Electric Power (EP), And/or optionally giving information on the result of the operation, and/or optionally giving an evaluation of the operation, and/or optionally charging the battery (EB), and/or optionally giving a result of the health evaluation, and/or optionally giving a result of the cleaning evaluation; and/or

The electric toothbrush with rotating Resonant Motor (RMT) is configured with at least one standby operating mode in which the Controller (CS), and/or the actuator (ED), and/or the rotating Resonant Motor (RM), and/or the damping Device (DP), and/or the Transmission (TM), and/or the battery (EB) are in standby; and/or

The electric toothbrush with rotary Resonance Motor (RMT) is configured to have at least one failure mode in which a function of a partial module of the electric toothbrush with rotary Resonance Motor (RMT) is limited and the electric toothbrush with rotary Resonance Motor (RMT) can selectively give a failure code, and/or a notice message, and/or a failure message; and/or

Said electric toothbrush with rotating Resonant Motor (RMT) comprising at least one control system; and/or

Said Controller (CS) comprises at least one control system; and/or

Under the direct or indirect action of the Controller (CS) and/or the control system, according to the input of the user, and/or the feedback of the actuating device (ED), and/or the feedback of the detecting device, and/or the feedback of the housing (EH), and/or the feedback of the rotary Resonant Motor (RM), and/or the feedback of the motor bracket (FB), and/or the feedback of the damping Device (DP), and/or the feedback of the transmission device (TM), and/or the feedback of the Controller (CS), and/or the feedback of the battery (EB), and/or the feedback of the Electric Power (EP), the electric toothbrush with a rotary Resonance Motor (RMT) is configured to have at least a function of selectively adopting different operation modes.

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