The invention belongs to the field of oral cavity cleaning daily necessities, and relates to a mouthpiece-type teeth-cleaning method.
Bass method, also known as gingival sulcus cleaning or horizontal flutter, is an effective method to remove plaque near the gingival margin and in the gingival sulcus.
Bass method requires the following conditions: a soft-bristled toothbrush should be selected, the toothbrush form, with a long axis of the tooth, an angle of 45 degrees to point in the apical direction (upward for upper jaw tooth, downward for lower jaw tooth), the gum-tooth interface area is pressed, one part of the bristles enters the gingival sulcus, one part of the bristles are spread on the gingival margin and extend into the adjacent gap as far as possible, and the bristles are horizontally vibrated by soft pressure for 10 times in a short distance in the front-back direction in situ. The toothbrush moved only about 1 mm while vibrating. For the linguopalatine side of the anterior teeth, if the arch is narrow, the toothbrush can be upright. The bristle enters the gingival sulcus and adjacent space at an angle of about 45 degrees and makes a short tremor against the long axis of the tooth. For the maxillofacial region, the action of brushing teeth is to press the bristles against the maxillofacial region, so that the hair ends go deep into the point space and make vibrations in direction of the front and back teeth. However, since the gingival sulcus and gingival margin are both arched curves, for the existing toothbrush, or electric toothbrush, or tooth cleaning device, the natural arched curve of the gingival margin cannot be fitted due to a single movement direction, so that it is difficult to implement the Bass method at each part of the gingival margin/gingival sulcus.
Recently, a toothbrush (Blizzident) customized according to the user's teeth has been developed. Customization occurs because the user's teeth are first 3D scanned, modeled, and then the toothbrush is made targeted according to the tooth model. When using Blizzident, you can complete the entire brushing process by chewing more than ten toothbrushes up and down, left and right. Blizzident has more than about 400 soft bristles, and the soft bristles and gums form a 45 degree angle, and each corner can be cleaned as it is customized to the user's teeth. However, the toothbrush still has no personalized actuation capability, but relies solely on the overall relative movement between the upper and lower dentitions of the oral cavity and the bristles to clean the teeth. Therefore, the brushing action of the toothbrush cannot fit the natural arch curve of the gingival sulcus, and the requirement of the Bass method cannot be met.
Aiming at the defects in the prior art, the invention aims to solve the problem that the existing teeth-cleaning method and device cannot really implement the Bass method, and provide a complete clean, efficient and convenient mouthpiece-type teeth-cleaning method for users.
The technical solution adopted by the invention is as follows:
A mouthpiece-type teeth-cleaning method, comprising:
Further, said establishing the correlation comprises:
Further, said establishing the digitized three-dimensional mouthpiece model matched with the three-dimensional tooth model specifically comprises:
Further, step S2 specifically comprises:
Further, step S4 specifically comprises: after establishing the dentition positional scribings of the three-dimensional tooth model and marking the occlusion detection area of the three-dimensional mouthpiece model, according to the corresponding relation with the upper dentition and the lower dentition of the tooth model, and according to the dentition spatial layout data of each dentition positional scribing and the cleaning requirement data corresponding to selected cleaning operation mode, marking groove operation scribings at corresponding parts of the surface area, except the occlusion detection area, of the surface of on the upper groove and the lower groove of the three-dimensional mouthpiece model, and establishing groove spatial layout data of each groove operation scribing;
Further, the cleaning operation is generated by the cleaning system and the cleaning operation mode is based on one or more combinations of the following three modes:
Further, manufacturing a finished mouthpiece for wearing by the user according to an established digital three-dimensional mouthpiece model, and the user wearing the finished mouthpiece to perform correlation detection in occlusion process, the detection specifically comprises:
Compared with the prior art, the mouthpiece-type teeth-cleaning method disclosed by the invention achieves the following technical effects:
In order that those skilled in the art may better understand the technical aspects of the present invention, the present invention will be described in further detail with reference to the accompanying drawings and detailed description.
The invention aims at customizing the mouthpiece structure of a mouthpiece-type teeth cleaner for implementing the Bass method for a user according to the shape and layout of the whole mouth teeth of the user, thereby realizing a novel teeth-cleaning method based on the mouthpiece.
The mouthpiece-type teeth-cleaning method disclosed by the embodiment of the invention comprises:
The present invention generates an excitation signal from an excitation source, which may be electric, pneumatic, or a combination thereof, in an alternating manner, i.e., a periodically alternating pattern, such as an intermittent pattern of alternating changes between active and inactive states. Upon activation of the activation signal, a cleaning operation, which may be a direct brushing action on the tooth surface, is controlled to be generated to effect cleaning of various positions of the tooth. The cleaning operation may be a direct applied brushing cleaning action against the tooth surface. Since the correlation between the cleaning operation and the cleaning action and each part of the teeth of the user is established in advance, the cleaning action can be different according to each part of the teeth of the user, such as: different parts such as a tooth surface, a tooth occlusal surface, a gingival sulcus, a diastema, a distal molar distal and middle surface and the like and different parts of teeth of different users have different sizes, areas, shapes and the like, and different cleaning actions are applied to carry out targeted cleaning. On the one hand, it is a fully automatic cleaning mode, on the other hand, it is also a personalized cleaning mode.
Referring to
Firstly, acquiring a spatial layout image of teeth of an oral cavity of a user, and establishing a digital three-dimensional tooth model of the teeth of the user.
The process for establishing the tooth model specifically comprises: carrying out image recognition on the full-mouth teeth or partial teeth of a user, wherein the recognition method comprises performing model taking or 3D scanning on the full-mouth dentitions (or partial dentitions) of the mouth of the user to obtain a spatial layout image of the teeth of the user, wherein the spatial layout image comprises the number of the teeth of the user, the shape and the size of a three-dimensional curved surface of the outer surface of each tooth, the distance between each adjacent tooth, the shape and the camber of a contact part between the tooth and the gingiva and the like, covering all spatial relation layouts of the medial (lingual, palatal) and lateral (labial, buccal), occlusal and incisal surfaces, and the distal and medial surfaces of the left and right distal molars of the user's teeth, thus obtaining a tooth model matched with the user's actual dentition.
Secondly, establishing a digital three-dimensional mouthpiece model matched with the three-dimensional tooth model according to the established three-dimensional tooth model, wherein a cleaning system is arranged on a groove of the three-dimensional mouthpiece model, the cleaning system and each part of teeth of the established three-dimensional tooth model have corresponding spatial relation layout, and cleaning of each part of teeth is realized by the cleaning system.
Thirdly, according to the established digital three-dimensional mouthpiece model, manufacturing a finished mouthpiece which is for wearing by the user.
Fourthly, the user wearing the finished mouthpiece, carrying out correlation detection in the occlusion process, triggering and generating the excitation signal after detecting the compliance, and then generating the cleaning action.
That is, the correlation includes: the correlation between the tooth model and the actual dentition of the user, the correlation between the upper and lower phatnomas of the mouthpiece model and the upper and lower dentitions of the tooth model, and the correlation between the cleaning system of the mouthpiece and each part of the groove of the mouthpiece model, and the correlation between the mouthpiece for wearing by the user and the actual dentition of the user are finally established.
In this embodiment, the cleaning operation is generated by the cleaning system and the cleaning operation mode is based on a combination of one or more of the following three modes:
Operation mode I:
In operation mode I, the cleaning system consists of an excitation source, an actuation module and a bristle module, the actuation module is controlled to act after the excitation source is started, the actuation module drives the bristle module to act, the bristle module consists of bristle clusters, and each part of a tooth is brushed by the bristle clusters.
In operation mode I, the signal generated by the excitation source may be an alternating pneumatic, hydraulic signal or voltage signal.
Operation mode II:
In operation mode II, the cleaning system consists of a plurality of conduits embedded in a groove, a bulge and an excitation source. After the excitation source is started, gas or liquid is intermittently blown into the conduits, so that the bulges are straightened and bent in time, and the bulges are changed between the straightened state and the bent state to form a motion track to brush relevant parts of teeth.
In operation mode II, the signal generated by the excitation source may be an alternating pneumatic or hydraulic signal.
Operation mode III:
In operation mode III, the cleaning system consists of a plurality of conduits, small holes and an excitation source. After the excitation source is started, gas is blown in the conduit, liquid or mist is sprayed outwards through the small holes, and the sprayed gas, liquid or mist impacts the outer surface of the tooth to clean relevant parts of the tooth. It should be noted that the three modes of operation are primarily directed to the cleaning of the diastema.
In operation mode III, the signal generated by the excitation source is an alternating pneumatic or hydraulic signal.
With regard to the selection of the cleaning operation mode, one preferred embodiment is: cleaning of each tooth part is accomplished by a combination of three or any two of the cleaning operations described above.
For example: the diastema cleft, the gingival sulcus, the adjacent gingival part, the tooth surface, the tooth occlusal surface and other parts are brushed and cleaned by the projection reciprocating action in cleaning operation mode II; aiming at the position of the diastema, a mode of spraying cleaning liquid through a small hole of a conduit in a cleaning operation mode III is adopted at the same time.
For another example: the diastema cleft, the gingival sulcus, the adjacent gingival part, the tooth surface, the tooth occlusal surface and other parts are brushed and cleaned by a bristle module in cleaning operation mode I. Aiming at the position of the diastema, a mode of spraying cleaning liquid through a small hole of a conduit in cleaning operation mode III is adopted at the same time.
For another example: aiming at the position of the diastema cleft, the cleaning liquid is sprayed through the small holes of the conduits in cleaning operation mode III, and the operation is convenient. The bristle module in cleaning operation mode I is used for brushing and cleaning the positions of the diastema cleft, the gingival sulcus, the tooth surface, the tooth occlusal surface and the like, the cleaning is cleaner, the gingival position adjacent to the gingival sulcus is brushed and cleaned through the reciprocating motion of the bulges in cleaning operation mode II, and the discomfort of the gingival position is reduced.
Referring to
In particular, at least one (i.e., one or more) region of each of the upper and lower dentition of the digitized three-dimensional tooth model is selected as the occlusal positioning region, and the selected portion is a portion where the upper and lower dentition can touch, such as an apical portion. More preferably, two upper incisors ( ) and two lower incisors ( ) in the middle of the dentition of the user (a tooth section, and a labial tooth surface position area and a lingual-palatal tooth surface position area adjacent to the section) are selected as occlusion positioning area.
Step S2: scribing an outer surface of dentition of the model according to the three-dimensional tooth model of the selected occlusion positioning area, and establishing a dentition positional scribing system of the three-dimensional tooth model.
Specifically, step S2 specifically comprises:
Step S21: according to the three-dimensional tooth model of the selected occlusion positioning area, scribing other surface areas of the outer surface of the dentition of the model except the occlusion positioning area to form a plurality of mutually connected positional scribing; therein, the scribings are classified into several categories according to different cleaning requirements of various parts of teeth. For example, for other surface areas of the outer surface of the three-dimensional tooth model in the normal state except the occlusion positioning area, the scribings are classified into the following categories: gingival sulcus positional scribing, tooth surface positional scribing, diastema positional scribing, tooth occlusal surface positional scribing, tooth section positional scribing and distal molar distal and middle surface positional scribing. As another example, for other surface areas of the outer surface of the three-dimensional tooth model in a state where the metal bracket type dental appliance is worn than the occlusion positioning area, the scribings are classified into the following categories: gingival sulcus positional scribing, tooth surface positional scribing, alveolar ridge and bracket diastema positional scribing, alveolar ridge side bracket sulcus positional scribing, apical side bracket sulcus positional scribing, bracket and apical diastema positional scribing, diastema positional scribing, alveolar ridge and bracket diastema positional scribing, bracket and apical diastema positional scribing, tooth occlusal surface positional scribing, tooth section positional scribing, and distal molar distimal positional scribing. Different classes of the positional scribings are preset in advance with different initial cleaning requirement parameters. The initial cleaning demand parameter may also include a selection of the three cleaning modes of operation described above, i.e., when the initial cleaning demand parameter is set, which cleaning mode is selected for which locations.
Specifically, the positional scribing is carried out on the basis of different brushing requirements of different parts. The gingival sulcus position refers to the area where the teeth are combined with the gums, and the gingival communication is usually an arch curve. The tooth surface part refers to the tooth surface area on the labial-buccal side and the lingual-palatal side of the teeth, the tooth occlusal surface part refers to the apical occlusal areas of the premolar teeth and the posterior molar teeth, and the tooth section position refers to the apical section area of the anterior teeth. The diastema region refers to the region formed by the gap between two adjacent teeth, and the distal molar mesiofacial region refers to the mesiofacial region of the left most molar and the rightmost molar near the occlusal space of the dentition. Those skilled in the art will appreciate that the scribings for their tooth locations may be the same or different for different user populations.
Taking cleaning operation mode I as an example, the initial cleaning requirement parameters include: the static inclination angle between the bristle and each brushing part, the motion period of the bristle, the motion direction of the bristle, the motion amplitude and other parameters. The initial cleaning requirement parameters can also include the flexibility parameter of the bristle material, the elasticity parameter of the bristle material, the diameter parameter of the bristle and the like. The preset initial cleaning requirement parameters are partially different for different categories.
Specifically regarding scribing a gingival sulcus position, initial cleaning requirement parameters of the gingival sulcus position are set as follows: Binchotan antibacterial sharpening fine bristles are selected for the bristles, the diameter parameter of the bristles is 0.01 mm, and the static inclination angle between the bristles and the inner tooth surface of the gingival sulcus is 45 degrees; the action mode of the bristle is a reciprocating symmetrical periodic motion, and the action period of the bristle is 500 ms. The included angle between the action direction of the bristle and the tangential direction of the arch curve of the gingival sulcus is less than 15 degrees, and the action amplitude of the bristle is 1 mm in the gingival sulcus. Taking diastema positional scribing as an example, the initial cleaning requirement parameters are set as follows: a flexible spiral bristle is selected for the bristle, the diameter parameter of the bristle material is 0.02 mm, and the static inclination angle between the bristle and the diastema is 90 degrees; the bristle motion mode is a back-and-forth asymmetric periodic motion, and the bristle motion period is 1000 ms; the action directions of the bristles are as follows: brushing from the apical end of the alveolar ridge of the diastema to the apical direction, and returning from the apical direction to the apical direction of the alveolar ridge. The action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms; the brush action amplitude is 60 degrees swing angle.
Taking operation mode II as an example, the initial cleaning requirement parameters include: intervals at which the bulges are arranged on the wall surface of the conduit tube, and three-dimensional shape data (including length, sectional shape and size of each section, bending direction) of each bulge in a non-excitation signal state are obtained.
For example, the initial cleaning requirement parameters set for cleaning the bulges of the gingival sulcus position are: the static inclination angle between the bulge axis and the inner tooth surface of the gingival sulcus is 45 degrees; the bulge motion mode is a reciprocating symmetrical periodic motion, and the bulge motion period is 800 ms; the bulge action direction is the tangential direction of the gingival sulcus arch arc curve, and the included angle is less than 15 degrees; the amplitude of the bulge motion is 2 mm run in the gingival sulcus.
The initial cleaning requirement parameters set for cleaning the bulges of the diastema position are as follows: the static inclination angle between the bulge axis and the diastema is 90 degrees; the bulge motion mode is a reciprocating asymmetric periodic motion, and the bulge motion period is 1000 ms. The bulge action direction is as follows: brushing from the crest end of the alveolar ridge of the diastema to the direction of the cusp, and returning to the direction of the crest end of the alveolar ridge from the direction of the cusp. The action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms. The amplitude of the bump motion is 60 degrees swing angle.
Taking operation mode III as an example, the initial cleaning requirement parameter includes: the opening position of the small hole of the conduit (for example: aligning the position, which is 1.5 mm away from the crest end of the alveolar ridge, of the diastema, the size of the aperture (for example: 0.5 mm), and the jet speed of the fluid (for example: 1 m/s).
Step S22: respectively establishing the dentition spatial layout data and the cleaning requirement data of the dentition positional scribings according to the image information of the dentition positional scribings and the initial cleaning requirement parameters of the dentition positional scribings after the dentition positional scribings and dividing are completed, wherein all the positional scribings and data attached thereto form the dentition positional scribing system of the tooth model. The initial cleaning requirement parameters give initial values of default states of scribing cleaning requirement data of various parts, and most parameters in the cleaning requirement data can be consistent with the values in the initial cleaning requirement parameters.
Specifically, the dentition positional scribing is oriented toward tooth to clean, and its cleaning demand data includes its cleaning operation mode (i.e., one or more of the three afore mentioned cleaning operation modes) selection and initial cleaning demand parameters, and its spatial layout data is based on captured dentition image information.
Taking cleaning operation mode I as an example, the types of dentition scribing and the setting of cleaning requirement data are described in detail:
Firstly, for the gingival sulcus positional scribing, the gingival sulcus position corresponds to a corresponding gingival sulcus of a user tooth, and the set cleaning requirement data are as follows: Binchotan antibacterial sharpening fine bristles are selected for the bristles, the diameter parameter of the bristles is 0.01 mm, and the static inclination angle between the bristles and the inner tooth surface of the gingival sulcus is 45 degrees; the action mode of the bristle is a reciprocating symmetrical periodic motion, and the action period of the bristle is 500 ms. The included angle between the action direction of the bristle and the tangential direction of the arch curve of the gingival sulcus is less than 15 degrees, and the action amplitude of the bristle is 1 mm in the gingival sulcus.
Secondly, for the tooth surface positional scribing, which has a corresponding tooth surface corresponding to the tooth surface positional scribing except for the occlusion positioning positional area, the cleaning requirement data set by the invention are as follows: brushing from root to tip. When the bristle is operated from the tooth root to the tooth tip direction, the speed is relatively high, and the strength is large. On the contrary, when the bristle returns from the tip to the root direction, the speed is relatively slow, and the strength is small. The stroke of the brushing action is 3-7 mm. In order to realize the brushing operation with asymmetric back-and-forth force, the alternating excitation signal needs to be designed in a waveform mode, so that the rising edge of the signal is steeper, and the falling edge is milder.
Thirdly, for the diastema positional scribing, the diastema position is formed by enclosing a plurality of curved surfaces of adjacent teeth of a user. The cleaning requirement data set by the invention are as follows: a flexible spiral bristle is selected for the bristle, the diameter parameter of the bristle material is 0.02 mm, and the static inclination angle between the bristle and the diastema is 90 degrees; the bristle motion mode is a back-and-forth asymmetric periodic motion, and the bristle motion period is 1000 ms; the action directions of the bristles are as follows: brushing from the apical end of the alveolar ridge of the diastema to the apical direction, and returning from the apical direction to the apical direction of the alveolar ridge. The action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms; the brush action amplitude is a 60-degree swing angle. In order to realize the brushing operation with asymmetric back-and-forth force, the intermittent excitation signal needs to be designed in a waveform mode, so that the rising edge of the signal is steeper, and the falling edge is milder.
The gap between the diastema positional scribing and the slot body operation scribing is relatively large, about 5-9 mm. Thus, the length of bristles required at this location is relatively long.
Fourthly, for the tooth occlusal surface positional scribing, which corresponds to the occlusal surface of each molar of the user, the occlusal surface positional scribings all have a corresponding tooth surface corresponding thereto. The cleaning requirement data set by the invention are as follows: brushing back and forth along the horizontal direction of the plane of the occlusal surface, wherein the stroke of the brushing action is 3-7 mm.
Fifthly, for tooth section positional scribing, which corresponds to the section of each front tooth of the user, on the three-dimensional model of the dentition of the user, the section positional scribings have a corresponding tooth section corresponding to the corresponding tooth section. The cleaning requirement data set by the invention are as follows: horizontal brushing brush. Of course, no cleaning operation can be performed for this location, i.e. no bristle module and corresponding actuation module are provided on the scribing of the corresponding slot operation location on the phatnoma.
Sixth, for the tooth distal molar distal and middle surface positional scribing corresponding to the left most molar and the rightmost molar of the tooth near the distal and middle area of the occlusal space, the distal molar distal and middle surface position has a corresponding molar distal and middle surface. The cleaning requirement data set by the invention are as follows: brushing from root to tip. When the bristle is operated from the tooth root to the tooth tip direction, the speed is relatively high, and the strength is large. On the contrary, when the bristle returns from the tip to the root direction, the speed is relatively slow, and the strength is small. The stroke of the brushing action is 3-7 mm. In order to realize the brushing operation with asymmetric back-and-forth force, the alternating excitation signal needs to be designed in a waveform mode, so that the rising edge of the signal is steeper, and the falling edge is milder.
Step S3: marking occlusion detection areas on corresponding parts of upper groove and lower groove of the three-dimensional mouthpiece model according to the occlusion positioning area.
Specifically, when the tangent planes of certain two front teeth of the digitized three-dimensional tooth model and the adjacent areas thereof are selected as occlusion positioning area, correspondingly, the end parts, corresponding to the occlusion positioning area, of the central part of the surface of the groove of the mouthpiece model are designed as occlusion detection areas, and the parts outside the occlusion detection areas are cleaning operation areas. That is, the cut surface of the upper front tooth corresponds to the bottom end surface of the middle trough body of the upper trough body of the shell, and the cut surface of the lower front tooth corresponds to the top end surface of the middle trough body of the lower trough body of the shell. The bottom end face of the surface of the middle section groove of the upper groove of the mouthpiece and the top end face of the surface of the middle section groove of the lower groove of the mouthpiece are respectively used as two occlusion detection areas.
Step S4: establishing a groove operation scribing system of the digital three-dimensional mouthpiece model according to the dentition positional scribing system of the three-dimensional tooth model.
Wherein, step S4 specifically comprises:
Step S41: after finishing the dentition positional scribings of the three-dimensional tooth model and marking the occlusion detection area of the three-dimensional mouthpiece model, according to the corresponding relation with the upper dentition and the lower dentition of the tooth model, and according to the dentition spatial layout data of each dentition positional scribing and the cleaning requirement data corresponding to the selected cleaning operation mode, on the three-dimensional mouthpiece model, marking a groove operation scribing at a corresponding position of a surface area of the surface of the lower groove except for the occlusion detection area, and dividing the groove operation scribing into the following categories according to different corresponding dentition positional scribings: gingival sulcus operation scribing, tooth surface operation scribing, diastema operation scribing, tooth occlusal surface operation scribing, tooth section operation scribing and distal molar distal and middle surface operation scribing.
Step S42: after the marking of the groove operation scribing is finished, establishing spatial layout data of each groove operation scribing, wherein when the spatial layout data enables the occlusion detection area to abut against the occlusion positioning area, a gap existing between each groove operation scribing and each corresponding dentition positional scribing; the spatial layout data of the groove operation scribing comprising gap data between each groove operation scribing and the corresponding dentition positional scribing, and the gap data can be the same or different at different positions.
Step S43: establishing operation requirement data of each groove operation scribing according to the spatial layout data of each groove operation scribing, the spatial layout data of each corresponding dentition positional scribing and the cleaning requirement data corresponding to the selected cleaning operation mode, wherein all the groove operation scribing and the data attached to all the groove operation scribing form a groove operation scribing system of the mouthpiece model.
In addition, in the step, a space for installing a pressure sensor is reserved in the groove, and the pressure sensor is used for detecting whether the occlusion positioning area and the occlusion detection area are abutted and whether the occlusion force reaches the standard.
Since the outer surface of the tooth model is divided into a plurality of scribings, each of which has a specific shape, correspondingly, a phatnoma-operated scribing having a spatial relation layout consistent with that of the dentition positional scribings on the tooth model is provided on the mouthpiece model. The spatial relation layout of the dentition positional scribing array and the groove operation scribing array is composed of an “upper dentition positional scribing array—upper groove operation scribing array marking spatial relation layout”, and a “lower dentition positional scribing array—lower groove operation scribing array marking spatial relation layout”.
The “upper dentition positional scribing array—upper groove operation scribing array marking space relation layout” is: when the occlusion positioning area of the upper dentition surface of the user abuts against the “occlusion detection area” of the upper dentition surface of the mouthpiece, the occlusion detection area in the upper groove of the user abuts against the occlusion positioning area of the upper dentition of the user, and all other groove operation scribings in the upper groove of the user (including a gingival sulcus operation scribing, a tooth surface operation scribing, a tooth occlusion surface operation scribing, a tooth section operation scribing, an diastema operation scribing and a distal molar distal and middle operation scribing) have certain spatial correlation with the scribings of other dentition positions on the upper dentition of the user, and certain gaps (such as 6 mm±3 mm) are reserved between the corresponding scribings with correlation.
The “lower dentition positional scribing array—lower groove operation scribing array marking spatial relation layout” is consistent with the spatial relation layout of the upper dentition and the upper groove, and will not be described in detail herein. That is, since the bite detection region is located at a position where the bite detection region is required to be in direct contact with the bite, no cleaning operation is applied, while for the remaining portion (the portion other than the bite location region) cleaning operation is required, and a certain gap is left between the dentition positional scribing and the groove operation scribing. Because the extension part of the bristle or the projection extending out of the surface of the groove has f length, the gap provides a spreading space for the reciprocating brushing action of the bristle or the reciprocating stretching and bending action of the projection, and the size of the gap is different for different dentition positional scribings. For example, in gingival sulcus and tooth surface, the gap is relatively small; in the diastema, the space is relatively large.
The operation requirement data of the groove operation scribing receives the cleaning requirement data of the corresponding dentition positional scribings, which is not a value range, but a specific numerical value of the operation requirement data of each groove operation scribing established according to the spatial layout data of each groove operation scribing and the cleaning requirement data of each corresponding dentition positional scribings.
Step S5: establishing a cleaning operation system of the cleaning system according to the groove operation scribing system of the three-dimensional mouthpiece model.
In the following, the process of establishing the cleaning operation system of the three-dimensional mouthpiece model according to the present invention will be described by three specific examples.
In this embodiment, tooth cleaning is achieved by means of cleaning operation mode I which is as follows: a plurality of actuation modules connected with the excitation sources are arranged in the mouthpiece, and the actuation modules receive the excitation signals and generate one or more groups of mechanical motions; the mechanical motion drives the bristle module arranged on the mouthpiece to perform reciprocating brushing so as to clean relevant parts of teeth.
The occlusion positioning area and the occlusion detection area are calibrated in advance, the dentition positional scribing system and the groove operation scribing system are established, and the cleaning operation system of the cleaning system needs to be established according to the groove operation scribing system.
In the embodiment, the process for establishing the cleaning operation system specifically comprises: Step S5-A-1: establishing a bristle module system of the three-dimensional mouthpiece model according to the groove operation scribing system of the three-dimensional mouthpiece model.
In step S5-A-1, after a groove operation scribing system of the three-dimensional mouthpiece model is established, the bristle modules on each groove operation scribing are arranged, and bristle spatial layout data and brushing requirement data of each bristle module are established according to groove spatial layout data and operation requirement data of each groove operation scribing and dentition spatial layout data of each corresponding dentition positional scribing, and thus all the bristle modules and data attached thereto form a bristle module system of the mouthpiece model.
The upper groove and the lower groove of the mouthpiece are designed, so that the layout of the bristle module arrays of the upper groove and the lower groove respectively has a corresponding relation with each scribing except the occlusion detection operation scribing in the upper groove and the lower groove operation scribing arrays.
The space relation layout of the “groove operation scribing array—groove brushing module array” is: when the occlusion positioning area of the surface of the dentition of the user abuts against the occlusion detection area of the surface of the dentition groove, the array of the bristle modules of the dentition groove of the user has “correlation” with scribing of various parts of the dentition of the user.
The “correlation” is represented by the fact that each bristle module on the user's phatnoma has a corresponding relationship in spatial layout with each positional scribing of the user's dentition, and the corresponding relationship here can be simply understood as specifying different actions in advance for different positions of teeth, such as tooth surface, gingival sulcus and the like, so that customized brushing can be performed according to the positions with different motions preset. On the parameters of the bristle material, the bristle size (length and thickness), the bristle implantation density, the brushing action direction, the brushing action amplitude and the like, each bristle module corresponding to the spatial layout of each positional scribing of the user dentition can be different according to different cleaning requirements of each positional scribing of the user dentition.
The spatial layout data of the bristle module in the operation scribing of the groove comprises position data of each bristle in the scribing of the groove on the surface of the scribing of the groove, and three-dimensional shape data (including length, sectional shapes and sizes of each section and the extending direction of each bristle) of each bristle in the non-excitation signal state.
Step S5-A-2: establishing an actuation module system of the three-dimensional mouthpiece model according to the bristle module system of the three-dimensional mouthpiece model.
In step S5-A-2, after the bristle module system of the three-dimensional mouthpiece model is established, each corresponding actuation module drives each bristle module to act is arranged in phatnoma of the mouthpiece model, and the actuation spatial layout data and the actuation requirement data of each corresponding actuation module are established according to the bristle spatial layout data and the brushing requirement data of each bristle module, and all the actuation modules and data attached thereto form the actuation module system of the mouthpiece model.
Since the bristle module is driven to move only by the action of the actuation module, after the space position layout relation of the bristle module is set, corresponding actuation modules are designed for the bristle module in the upper groove and the lower groove of the mouthpiece position. The action direction and the action amplitude of the actuation module make corresponding customized design according to parameters such as the brushing action direction and the brushing action amplitude of the corresponding bristle module.
In the embodiment, the mouthpiece is composed of an outer coating layer made of a soft elastic material and an inner framework which is used for supporting the mouthpiece and is made of a hard material, the bristle module comprises a tray and bristles positioned on the tray, the bristles penetrate out of the surface of the outer coating layer, and the actuation module is positioned inside the mouthpiece and closed by the outer coating layer.
In the embodiment, the actuation module comprises a driving unit and a transmission unit, wherein the driving unit is connected with an excitation source and is used for receiving an excitation signal generated by the excitation source and driving the transmission unit to act, and the transmission unit is connected with a bristle module so as to drive the bristle module to act in a set manner.
The driving unit may be a pneumatic driving unit or a voltage driving unit.
The function of the pneumatic driving unit is as follows: converting the air pressure change conducted by the excitation source through the main conduit and the branch conduit into the telescopic action of the air pressure driving unit, wherein the excitation source is an air pump and particularly can be a piston pump arranged in the handle, and when the pumping action is executed, the most atmospheric pressure of the excitation source is matched with the air pressure required by the air pressure actuation module to reach the rated action amplitude, such as: the most atmospheric pressure may be 1.5 standard atmospheres.
Referring to
When the air pump in the handle performs a pumping action, the conduit and the branch conduit conduct high air pressure to the semi-hollow tube 81, so that the air pressure in the semi-hollow tube 81 increases, thereby causing the length of the semi-hollow tube 81 to increase, that is, the distance between the closed end and the open end to increase, as shown in
The function of the voltage driving unit is as follows: converting the voltage change conducted by the excitation source through the electric lead into the telescopic action of the voltage driving unit, wherein the excitation source is an electric signal. Referring to
When the power supply applies a voltage to the electrodes across the artificial muscle 41, the artificial muscle contracts. When the voltage on the electrodes (A, B) at both ends of the artificial muscle 41 is released, the artificial muscle is stretched and restored to the original shape. When a power source reciprocally applies a voltage to the electrodes at both ends of the artificial muscle 41 and releases the voltage, the artificial muscle 41 is driven to reciprocate in a contracting and elongating stretching motion. When the artificial muscle is driven to act, the maximum voltage of the artificial muscle is matched with the voltage required by the voltage driving unit to reach the rated action amplitude. Such as: the maximum voltage may be 24 volts. The turn-on and turn-off of the voltage driving unit can be controlled by the pulse of the single chip microcomputer.
The function of the transmission unit is as follows: converting the telescopic action of the driving unit into the swinging brushing action of the bristle module.
In one embodiment of the invention, the transmission unit is a 7-shaped connecting rod or a T-shaped supporting rod, wherein the 7-shaped connecting rod comprises a first cross rod and a first vertical handle which are integrally formed, and the T-shaped supporting rod comprises a second cross rod and a second vertical handle which are integrally formed.
The first cross rod of the 7-shaped connecting rod is flat, the first cross rod is fixedly connected with the tray of the bristle module or embedded into the tray, and the first vertical handle is connected with the air pressure driving unit or the voltage driving unit; the second cross rod of the T-shaped supporting rod is flat, the second cross rod is fixedly connected with the tray of the bristle module or embedded into the tray, and the second vertical handle is fixed on the mouthpiece.
Referring to
Therefore, according to the difference between the two pneumatic driving units and the transmission units, the actuation module has four construction modes: pneumatic driving+7-shaped connecting rod transmission, pneumatic driving+T-shaped supporting rod transmission, voltage driving+7-shaped connecting rod transmission and voltage driving+T-shaped supporting rod transmission.
These four solutions are further described below.
In Solution I, the actuation module is composed of a pneumatic driving unit and a 7-shaped connecting rod. When the closed end of the semi-hollow tube 81 of the actuation module reciprocates to perform telescopic movement, the first vertical handle of the 7-shaped connecting rod is pushed and pulled to reciprocate, so that the first transverse handle of the 7-shaped connecting rod is driven to reciprocate and swing, and the tray of the bristle module is driven to reciprocate and swing, so that bristle clusters implanted on the tray perform brushing actions back and forth according to the customized direction and amplitude.
In Solution II, the actuation module consists of a pneumatic actuation unit and a T-shaped supporting rod. When the closed end of the semi-hollow tube 81 of the actuation module reciprocates for telescopic movement, the tray-shaped second transverse handle of the T-shaped supporting rod is pushed and pulled to reciprocate and swing, so that the tray of the bristle module is driven to reciprocate and swing, and bristle clusters implanted on the tray perform brushing actions back and forth according to the customized direction and amplitude.
In Solution III, the actuation module is composed of a voltage driving unit and a 7-shaped connecting rod. When the bar-shaped artificial muscle of the actuation module reciprocates to perform telescopic motion, the first vertical handle of the 7-shaped connecting rod is pushed and pulled to perform reciprocating motion, so that the first transverse handle of the 7-shaped connecting rod is driven to perform reciprocating swing, and the tray of the bristle module is driven to perform reciprocating swing, so that bristle clusters implanted on the tray perform brushing actions back and forth according to the customized direction and amplitude.
Referring to
There may be hundreds (e.g., 200-800) of bristle modules on the upper and lower groove surfaces of the mouthpiece portion of a dentifrice, respectively. A plurality of bristles (e.g., 10-100 bristles) are implanted into each bristle module to form a bristle cluster, alternatively, one bristle module corresponds to one actuation module, or a plurality of bristle modules with the same or substantially the same action amplitude and direction share the same actuation module, so that the arrangement number of the actuation modules can be reduced.
In another embodiment of the invention, the actuation module is an artificial muscle, the bristle module consists of a flocking tray and one or a cluster of bristles fixed by the flocking tray, the actuation source is a voltage signal, and the actuation module can directly pull the bristle module by one or more artificial muscles without the transmission unit in the solution I to Solution IV. The flocking tray is in a vertical tube shape, the bottom of the tray is fixed on the inner framework, a single bristle or bristle cluster is fixed on the top of the tray, and at least one artificial muscle is arranged. One end of the artificial muscle is connected with the flocking tray, the other end of the artificial muscle is fixed on the inner framework, two ends of the artificial muscle are respectively used as two different electrode points, and the flocking tray is surrounded when the artificial muscle has a plurality of bristles. The excitation source controls the artificial muscle to contract or relax by applying voltage to the electrode points of the artificial muscle so as to drive the tray to act.
Referring specifically to
Because of the structural particularity of the gingival sulcus position, better cleaning effect can be brought by brushing along different directions of the gingival sulcus curve respectively. In a preferred embodiment of the invention, aiming at the gingival sulcus position, a bristle module is set to be controlled to brush by at least two artificial muscles, a plurality of artificial muscles are arranged around the flocking tray of the bristle module, the plurality of artificial muscles are set to be driven by a plurality of sets of excitation signals with phase differences, and the plurality of sets of excitation signals are set, by cooperation of the excitation signals with different voltage phase differences, such that when part of the artificial muscles contract, the rest of the artificial muscles are stretched, and the bristle module is driven to move towards the contraction direction of the artificial muscles. The bristle module is therefore driven to have a plurality of different brushing angles to the gingival sulcus position.
Although the use of two artificial muscles arranged at ninety degrees enables the bristles to alternate in the tangential direction of the gingival sulcus curve and the normal direction of the teeth, the two artificial muscles have a factor of instability in the direction of motion, as shown in
The specific layout and operation modes of the bristle module and the actuation module are exemplified as follows:
First brushing action: the brushing action is performed by the bristle module facing the gingival sulcus positional scribing.
The bristle module facing the gingival sulcus positional scribing comprises a gingival sulcus positional scribing of each tooth on the jaw side of the upper dentition, a gingival sulcus positional scribing of each tooth on the cheek side of the upper dentition, a gingival sulcus positional scribing of each tooth on the tongue side of the lower dentition and a gingival sulcus positional scribing of each tooth on the cheek side of the lower dentition corresponding to the gingival sulcus positional scribing of each tooth of a user. Soft and elastic sharpening fine bristles are adopted for the bristles on the gingival sulcus bristle module. Due to the design, the bristles on the gingival sulcus bristle module can easily extend into the gingival sulcus to remove stains such as plaque and the like, and the gums are not damaged. Under the driving of the actuation module, the bristle module of each gingival sulcus position performs a back-and-forth transverse brushing action along the tangential direction of the gingival sulcus curve of the gingival sulcus position.
Second brushing action: the brushing action is performed by the bristle module facing the tooth surface positional scribing.
The bristle module facing the tooth surface positional scribing comprises a tooth surface positional scribing of each tooth on the jaw side of the upper dentition, a tooth surface positional scribing of each tooth on the cheek side of the upper dentition, a distal molar distal and middle surface positional scribing of the upper dentition, a tooth surface of each tooth on the lingual side of the lower dentition, a tooth surface of each tooth on the cheek side of the lower dentition and a a distal molar distal and middle surface positional scribing of the lower dentition. A soft and elastic bristle is adopted for bristle module in the tooth surface positional scribing, the flocking density is increased, dental plaque attached on the tooth surface can be effectively cleaned, and enamel is not damaged. Under the driving of the actuation module, the bristle module corresponding to the tooth surface part is made to brush along the tooth surface part from the position close to the gingiva to the tooth tip direction.
Third brushing action: the brushing action is performed by the bristle module facing the diastema positional scribing.
The bristle module facing the diastema positional scribing corresponds to the diastema between each tooth of the user and comprises the diastema between each tooth on the jaw side of the upper dentition, the diastema between each tooth on the cheek side of the upper dentition, the diastema between each tooth on the lingual side of the lower dentition and the diastema between each tooth on the cheek side of the lower dentition.
The bristle materials of the scribing bristle module in the diastema positional scribing are mixed and matched, namely: a soft and elastic sharpening fine bristle is adopted at the end part close to the alveolar ridge gingival mastoid positional scribing, so that the discomfort caused by mechanical stimulation to the alveolar ridge gingival mastoid positional scribing is avoided as much as possible, and the gingiva is protected. A spiral bristle with good elasticity and high toughness is adopted below the end part, so that the spiral bristle can easily extend into a tooth gap to remove stains such as plaque or food residues. Also, the bristle length of the diastema may be longer than that of other bristle modules depending on the size of the diastema. Under the driving of the actuation module, the bristle module corresponding to the diastema position is brushed along the crevice of the diastema position from the end part of the diastema close to the alveolar ridge gingival mastoid to the direction of the empty apical part.
Fourth brushing action: the brushing action is performed by the bristle module facing the occlusal surface positional scribing.
The bristle module facing the occlusal surface positional scribing, corresponding to the occlusal surface of each rear tooth of the user, comprises an occlusal surface positional scribing of the upper left 4-upper left 8 of the upper dentition, an occlusal surface positional scribing of the upper right 4-upper right 8 of the upper dentition, an occlusal surface positional scribing of the upper left 4-upper left 8 of the lower dentition and an occlusal surface positional scribing of the upper right 4-upper right 8 of the lower dentition. The bristle module facing the occlusal surface positional scribing adopts spiral bristles which are good in elasticity and strong in toughness. Under the driving of the actuation module, the bristle module corresponding to each occlusal surface position is made to brush back and forth along the horizontal direction of the meshing surface part.
The correlation between dentition positional scribings and mouthpiece groove operation scribings is not necessarily one-to-one correspondence. Such as: a groove occlusal surface operation scribing corresponds to each occlusal surface positional scribing of the dentition. Each gingival sulcus positional scribing of the dentition can be provided with a plurality of corresponding groove gingival sulcus operation scribings so as to realize tangential brushing operation. Because the gingival sulcus is a curve, two or more (such as three) gingival sulcus operation scribings are required to correspond to each gingival sulcus positional scribing on the groove so as to realize the fitting of a plurality of straight line segments to the gingival sulcus curve.
Therefore, the requirements of the gingival sulcus tangential brushing operation by the Bass method are met. One or more corresponding operation scribings may be provided for scribings other than the gingival sulcus positional scribings.
Alternatively, at least two (for example, three) bristle modules are correspondingly arranged on each gingival sulcus operation scribing, the brushing direction of each bristle module is different, and therefore the arched curve of the gingival sulcus position can be better fitted.
A more preferred embodiment is provided that: aiming at the gingival sulcus position, each bristle module is set to be controlled to brush by two actuation modules, the two actuation modules alternately control the bristle modules to brush alternately along the tangential direction of the gingival sulcus curve and the normal direction of the gingival sulcus curve. Aiming at other positions of the dentition, each bristle module is set to be controlled to brush by one actuation module.
Step S5-A-3: establishing an excitation signal system of the three-dimensional mouthpiece model according to an actuation module system of the three-dimensional mouthpiece model.
In step S5-A-3, after an actuation module system of the three-dimensional mouthpiece model is established, an excitation signal source for controlling the actuation module to generate mechanical motion is arranged inside the mouthpiece model, and excitation signal data of the excitation signal source is established according to actuation requirement data of each actuation module, wherein the excitation signal source and the excitation signal data attached thereto form the excitation signal system of the mouthpiece model.
One or more excitation signal sources can be arranged, and when the excitation signal sources are arranged into a plurality, the power amplitudes of the excitation signal sources can be different. For example, the excitation signal sources with the same power amplitude are arranged for cleaning all gingival sulcus positions, the excitation signal sources with the same power amplitude are arranged for cleaning all tooth surface parts, and the like. For the positions with basically the same brushing force requirement, the excitation signal sources with the same power amplitude are arranged.
In order to realize the asymmetric cleaning operation requirements of the back and forth brushing force of the tooth surface positional scribing and the diastema positional scribing, the waveform design is preferably carried out on the alternating excitation signal, so that the rising edge of the signal is steeper, and the falling edge is milder.
Taking the tooth surface brushing as an example, a brushing cycle is set to brush from the part close to the gingival sulcus to the apical part, which is defined as the process of going forward, and then to brush back from the apical part to the gingival sulcus, which is defined as the process of going back. Due to the fact that different excitation signals are applied to the excitation sources, the speed of going forward is high, and the speed of going back is low. As a result, the bristles do not quickly stick to the gingival sulcus, which results in poor user experience In order to realize the difference between the rising d and the falling edge of the signal in one period, the direct-current voltage signal with the corresponding voltage value can be generated by controlling the duty ratio of the PWM signal at the excitation signal source. For an actuation module corresponding to a bristle unit on the diastema operation scribing and the tooth surface operation scribing, the alternating excitation signal is asymmetric within one period. For example, a rising edge reaches a peak voltage from zero within 150 ms, and the peak voltage is kept for 50 ms; the falling edge takes 750 ms to gradually drop from the peak voltage to zero and remains at zero voltage for 50 ms. For the actuation module corresponding to the bristle module on the gingival sulcus operation scribing, the alternating excitation signal is symmetrical in one period. The rising edge reaches the peak voltage from zero in 350 ms, and the peak voltage is kept for 50 ms, the falling edge gradually drops from peak voltage to zero for 350 ms and is held at zero voltage for 50 ms.
The dentition positional scribing system, the groove operation scribing system, the bristle module system, the actuation module system and the excitation signal system have sequentially corresponding mapping relationships, and the mapping relationships enable a latter action requirement to be determined on the basis of a former action requirement.
In order to fully meet the requirements of the Bass method, different types of materials can be adopted by each bristle module according to each position of the user dentition corresponding to the bristle module, and the bristle modules have different action directions. A dentifrice shell portion has hundreds (e.g., 200-800) of bristle modules on the inner wall of the phatnoma. On each bristle module, several bristles (e.g., 10-100) are implanted.
The steps S5-A-1 to S5-A-3 complete the establishment of a digitalized three-dimensional mouthpiece model, wherein the establishment not only comprises a static spatial layout, but also comprises a spatial layout of a groove position, a bristle module, an actuation module and an excitation source, and it further comprises a dynamic cleaning data layout, namely the action requirements of the bristle module, the actuation module and the excitation source signals respectively.
Finally, according to the established digital three-dimensional mouthpiece model, a finished mouthpiece for wearing by the user is manufactured.
In this embodiment, the tooth cleaning is performed in cleaning operation mode II. The cleaning operation mode II comprises that: a conduit is embedded in the mouthpiece, one end of the conduit is connected with an excitation source, a bulge is arranged on the wall surface of the conduit, the bulge is a hollow tube communicated with a conduit channel, and the excitation source generates alternating excitation signals to control the bulge to perform reciprocating straightening and bending actions so as to clean relevant parts of teeth.
The occlusion positioning area and the occlusion detection area are calibrated in advance, the dentition position system and the groove operation scribing system are established, and the cleaning operation system of the cleaning system needs to be established according to the groove operation scribing system.
In the embodiment, the process for establishing the cleaning operation system specifically comprises: Step S5-B-1: establishing a bulge module system of the three-dimensional mouthpiece model according to the groove operation scribing system of the three-dimensional mouthpiece model.
Step S5-B-1 specifically comprises: after a groove operation scribing system of the three-dimensional mouthpiece model is established, arranging the bulge on each groove operation scribing, and establishing bulge spatial layout data and brushing requirement data of each bulge module according to spatial layout data and operation requirement data of each groove operation scribing and spatial layout data of each corresponding dentition positional scribing, and all the bulge modules and data attached thereto form the bulge module system of the mouthpiece model.
The brushing requirement data for the bump module in this embodiment is exemplified as follows: The brushing requirement data of each bulge in the bulge module of the gingival sulcus operation scribing is preset as follows: the static inclination angle between the bulge axis and the inner tooth surface of the gingival sulcus is 45 degrees; the bulge motion mode is a reciprocating symmetrical periodic motion, and the bulge motion period is 800 ms; the bulge action direction is the tangential direction of the gingival sulcus arch arc curve, and the included angle is less than 15 degrees; the amplitude of the bulge motion is 2 mm run in the gingival sulcus.
The brushing requirement data of each bulge in the bulge module of the diastema operation scribing are preset as follows: the static inclination angle between the bulge axis and the diastema is 90 degrees; the bulge motion mode is a reciprocating asymmetric periodic motion, and the bulge motion period is 1000 ms; the bulge action direction is as follows: brushing from the crest end of the alveolar ridge of the diastema to the direction of the cusp, and returning to the direction of the crest end of the alveolar ridge from the direction of the cusp; the action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms; the amplitude of the bump motion is a 60-degree swing angle.
Step S5-B-2: establishing a conduit system of the three-dimensional mouthpiece model according to the bulge module system of the three-dimensional mouthpiece model.
In step S5-B-2, after a bulge module system of the three-dimensional mouthpiece model is established, a conduit for conveying an excitation signal to each bulge on each bulge module is arranged in a mouthpiece of the mouthpiece model and comprises a main conduit and each branch conduit, conduit spatial layout data of each conduit is established according to spatial layout data and brushing requirement data of each bulge module, and all of the conduits and data attached thereto form the conduit system of the mouthpiece model.
The dentition positional scribing system, the groove operation scribing system, the bulge module system and the conduit system have sequentially corresponding mapping relationships.
Referring to
Under the normal state (i.e. when the pump module does not perform pumping action), the bulge is shaped by preset stress according to the requirements of the bulge module system due to the material of the bulge, and the bulge is curved in the preset direction as shown in
Referring now to
Wherein, the occlusion positioning area and the occlusion detection area are calibrated in advance, the dentition position system and the groove operation scribing system are established, and the cleaning operation system of the cleaning system needs to be established according to the groove operation scribing system.
In the embodiment, the process for establishing the cleaning operation system specifically comprises: Step S5-C-1: establishing a small hole opening system of the three-dimensional mouthpiece model according to the groove operation scribing system of the three-dimensional mouthpiece model.
Step S5-C-1 specifically comprises: after the groove operation scribing system of the three-dimensional mouthpiece model is established, arranging small hole openings on each groove operation scribing, and establishing spatial layout data of each small hole opening according to groove spatial layout data and operation requirement data of each groove operation scribing and dentition spatial layout data of each corresponding dentition positional scribing, wherein all the small hole openings and data attached thereto form the small hole opening system of the mouthpiece model, such as the aperture of the small hole.
Step S5-C-2: establishing a conduit system of the three-dimensional mouthpiece model according to the small hole opening system of the three-dimensional mouthpiece model, such as the number of conduits, the inner diameter of the conduits and the like.
In step S5-C-2, the method further comprises, after the small hole opening system of the three-dimensional mouthpiece model is established, a conduit for conveying excitation signals to each small hole opening is arranged in the phatnoma of the mouthpiece model and comprising a main conduit and each branch conduit, the spatial layout data of each conduit according to the spatial layout data of each small hole opening is established, and all the conduits and data attached thereto form the conduit system of the mouthpiece model, the excitation source spraying liquid, gas or gas-liquid mixed mist to a relevant position of the tooth through the conduit and the small hole opening so as to clean the relevant position of the tooth. The small hole formed in the conduit should correspond to the opening small hole formed in the groove operation scribing.
The dentition positional scribing system, the groove operation scribing system, the small hole opening system and the conduit system have sequentially corresponding mapping relationships.
The working principle of cleaning by adopting the conduit and the small holes in the embodiment is as follows: A plurality of opening small holes 32 are formed in relevant parts of the groove of the mouthpiece, the opening small holes 32 preferably correspond to interdental seams of teeth of a user, one ends of the plurality of opening small holes 32 are connected with conduits 31 embedded in the mouthpiece, one ends of the conduits 31 are also provided with small holes and correspond to the positions of the opening small holes 32 in the groove, so that the conduits 31 are communicated with the opening small holes 32. The other ends of the plurality of conduits 31 extend into the handle and are connected with the pump module through a main conduit, and liquid, gas or mist is sprayed out of the small opening holes 32 under the pumping action of the pump module to clean the crevices.
Finally, according to different cleaning operation modes, a digitalized three-dimensional mouthpiece model is established, and a finished mouthpiece for wearing by the user is manufactured.
Specifically, the user's dentifrice shell portion is made according to the user's aforementioned dentifrice shell portion design. Taking the selected cleaning operation mode I as an example, the manufacturing content comprises an inner framework, an outer coating layer, an actuation module, a bristle module and the like of a mouthpiece portion, and a 3D printing process, a flocking process and the like are specifically used in the manufacturing method. Taking the selected cleaning operation mode II as an example, the manufacturing content comprises an inner framework, an outer coating, a conduit, a bulge and the like of the mouthpiece portion. Moreover, a pressure sensor and a signal transmission wire thereof are embedded in the groove of the mouthpiece part. The embedded part of the pressure sensor is the inside of the groove corresponding to the “occlusion detection area” of the surface of the groove. To facilitate handling by the user, a handle portion is also formed to mate with the shell, the handle having a space therein for receiving an excitation source and other auxiliary components, thereby forming the shell dentifrice of the user.
After the finished mouthpiece is manufactured, the user wears the finished mouthpiece to carry out correlation detection in occlusion process, wherein the detection process specifically comprises:
In particular, the user places the dentifrice shell portion into the oral cavity such that the upper and lower dentitions are aligned with the upper and lower grooves of the shell portion, initiating an occlusal action, with the “occlusal locating areas” of the upper and lower dentitions of the user abutting the “occlusal detection areas” of the upper and lower phatnomas of the shell, respectively, at which point the “user upper dentition—mouthpiece upper groove spatial relation layout” is consistent with the “the upper dentition positional scribing array—upper groove operation scribing array marking spatial relation layout”, and the “user lower dentition—mouthpiece lower groove spatial relation layout” is consistent with the “the lower dentition positional scribing array—the lower groove operation scribing array marking spatial relation layout”.
Then whether the pressure value generated by occlusion reaches a set threshold value and lasts for a set time interval is detected. Due to the fact that the pressure sensor is installed in the phatnoma, after the pressure sensor detects the pressure, the signal is sent to the processor to judge whether the pressure value meets the standard or not.
When the pressure value reaches a threshold value and the duration exceeds a set time interval (for example, exceeds 500 milliseconds), an excitation source is triggered to generate an alternating excitation signal, and then the cleaning operation and the cleaning action generation are controlled. When it is detected that the pressure value has not reached a threshold value or has not reached a set time interval (for example, not exceeding 500 milliseconds), the cleaning operation and the cleaning action are controlled to stop.
In operation mode I, after an excitation signal is generated by an excitation source, the actuation module starts to do reciprocating motion so as to drive the bristle module to perform reciprocating brushing on various parts of teeth; in operation mode II, when the excitation source intermittently generates excitation signals, the pressure in the main conduit and each branch conduit is triggered to increase and decrease, so that the pressure in the bulge increases and decreases, and the bulge carries out reciprocating telescopic motion to brush each position of the tooth; in operation mode III, when an excitation signal is generated intermittently by the excitation source, the conduit is triggered to inject gas, liquid or mist outwards through the opening small hole so as to clean various parts of teeth. Due to the fact that the user teeth are subjected to mold taking and positional scribing in advance, individual differences exist in the amplitude, the direction, the frequency and even the selection of bristle materials according to different operation areas.
In order to more conveniently illustrate the correlation establishing process of the present invention, an embodiment of cleaning of gingival sulcus position and diastema position will now be described by way of example from the entire dynamic change of “cleaning demand data-operation demand data-brushing demand data-actuation demand data-excitation signal data”.
Initial cleaning requirement parameters for gingival sulcus positional scribing: the corresponding bristle type is a sharpened fine bristle, the diameter parameter of the bristle material is 0.01-0.02 mm, and the static inclination angle between the bristle and the inner tooth surface of the gingival sulcus is 45 degrees. The action mode of the bristle is a reciprocating symmetrical periodic motion, and the action period of the bristle is 800 ms. The included angle between the action direction of the bristle and the tangential direction of the arch curve of the gingival sulcus is less than 15 degrees, and the action amplitude of the bristle is 1 mm run in the gingival sulcus. Initial cleaning requirement parameters for diastema positional scribing: the corresponding bristle type is a flexible spiral bristle, the diameter parameter of the bristle material is 0.02-0.03 mm, the static inclination angle between the bristle and the diastema is 90 degrees, the action mode of the bristle is a reciprocating asymmetric periodic motion, and the action period of the bristle is 1000 ms. The action directions of the bristles are as follows: brushing from the apical end of the alveolar ridge of the diastema to the apical direction, and returning from the apical direction to the apical direction of the alveolar ridge. The action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms. The brush action amplitude is a 60-degree swing angle.
The initial cleaning requirement parameter gives the initial value range of the default state of scribing cleaning requirement data of various parts. Most of the parameters in the cleaning demand data may be consistent with the values in the initial cleaning demand parameters. The operation requirement data of the groove operation scribing receives the cleaning requirement data of the corresponding dentition positional scribings, which is not a value range, but a specific numerical value of the operation requirement data of each groove operation scribing established according to the spatial layout data of each groove operation scribing and the cleaning requirement data of each corresponding dentition positional scribings. The brushing requirement data of the bristle modules in the mouthpiece groove operation scribing receive the operation requirement data of the corresponding groove operation scribing, and the spatial layout data and the brushing requirement data of each bristle module are established according to the spatial layout data and the operation requirement data of each groove operation scribing. Actuation requirement data of the actuation modules in the mouthpiece groove operation scribing receive brushing requirement data of the bristle modules in the corresponding mouthpiece groove operation scribing, and corresponding actuation requirement data are established according to the spatial layout data and the brushing requirement data of the bristle modules and the spatial layout data of the corresponding actuation modules. The excitation signal data in the mouthpiece receives the actuation requirement data of the actuation modules in the mouthpiece groove operation scribing, and the excitation signal data of the excitation signal source is established according to the actuation requirement data of each actuation module.
An example of operation requirement data in a mouthpiece groove operational scribing is as follows. Operation requirement data of gingival sulcus operation scribing: the type of bristle is sharpened fine bristle, the diameter parameter of bristle is 0.01 mm, and the static inclination angle between bristle and inner tooth surface of gingival sulcus is 45 degrees; the bristle motion mode is a back-and-forth symmetrical periodic motion, and the bristle motion period is 800 ms; the included angle between the action direction of the bristle and the tangential direction of the arch curve of the gingival sulcus is less than 15 degrees, and the action amplitude of the bristle is 1 mm run in the gingival sulcus. The operation requirement data of the diastema operation scribing are as follows: the bristle type is flexible spiral bristle, the diameter parameter of bristle material is 0.02 mm, and the static inclination angle between bristle and diastema is 90 degrees; the bristle motion mode is a back-and-forth asymmetric periodic motion, and the bristle motion period is 1000 ms; the action directions of the bristles are as follows: brushing from the crest end of the alveolar ridge of the diastema to the direction of the cusp, and returning to the direction of the crest end of the alveolar ridge from the direction of the cusp; the action time from the apical brush of the alveolar ridge to the apical direction is 200 ms, and the action time from the apical direction back to the apical direction of the alveolar ridge is 800 ms. The brush action amplitude is a 60-degree swing angle.
An example of brushing demand data for a bristle module in a mouthpiece groove operation scribing is as follows. Brushing requirement data of a bristle module corresponding to gingival sulcus operation scribing: the type of bristle is sharpened fine bristle, the diameter parameter of bristle is 0.01 mm, and the static inclination angle between bristle and inner tooth surface of gingival sulcus is 45 degrees; the bristle motion mode is a back-and-forth symmetrical periodic motion, and the bristle motion period is 800 ms; the included angle between the action direction of the bristle and the tangential direction of the arch curve of the gingival sulcus is less than 15 degrees, and the action amplitude of the bristle is 1 mm run in the gingival sulcus. Brushing requirement data of a bristle module for diastema operation scribing: the bristle type is flexible spiral bristle, the diameter parameter of bristle material is 0.02 mm, and the static inclination angle between bristle and diastema is 90 degrees; the bristle motion mode is a back-and-forth asymmetric periodic motion, and the bristle motion period is 1000 ms; the action directions of the bristles are as follows: brushing from the crest end of the alveolar ridge of the diastema to the direction of the cusp, and returning to the direction of the crest end of the alveolar ridge from the direction of the cusp; the action time from the apical brush of the alveolar ridge to the apical direction of the crown is 200 ms, and the action time from the apical direction to the apical direction of the alveolar ridge is 800 ms; the brush action amplitude is a 60-degree swing angle.
Examples of actuation requirement data for an actuation module in a mouthpiece groove operation scribing are as follows. Actuation requirement data of the actuation module corresponding to the gingival sulcus operation scribing are as follows: the mechanical motion mode is a back-and-forth symmetrical periodic motion, and the mechanical motion period is 800 ms; the mechanical motion amplitude is 1 mm run. Actuation requirement data of the actuation module corresponding to the diastema operation scribing are as follows: the mechanical motion mode is a back-and-forth asymmetric periodic motion, and the mechanical motion period is 1000 ms; the mechanical motion time is 200 ms for contraction time and 800 ms for relaxation time; the mechanical motion amplitude is 2 mm.
The excitation signal data in the mouthpiece is exemplified as follows. For an actuation module on a gingival sulcus operation scribing, the alternating excitation signal of the actuation module is symmetrical within one period, the rising edge reaches a peak voltage of 16V from zero within 350 ms, and the peak voltage is kept for 50 ms; the falling edge is ramped from peak voltage 16 V to zero for 350 ms and is held at zero voltage for 50 ms. For the actuation modules on the diastema operation scribing and tooth surface operation scribing, the alternating excitation signal is asymmetric for one cycle, the rising edge reaches a peak voltage of 16 V from zero in 150 ms, and remains at the peak voltage for 50 ms, while the falling edge takes 750 ms to gradually drop from the peak voltage of 16 V to zero and remains at zero voltage for 50 ms.
According to the mouthpiece-type teeth-cleaning method disclosed by the embodiment of the invention, the correlation between the tooth model and the mouthpiece model and the correlation between the tooth model and the cleaning system on the mouthpiece model are established, so that a user can carry out omnibearing automatic and personalized cleaning when wearing the mouthpiece.
Compared with the prior art, the mouthpiece-type teeth-cleaning method disclosed by the embodiment of the invention has the advantages that a user does not need to move the cleaning device everywhere in the oral cavity, can effectively clean different parts of teeth at the same time only by performing occlusion and releasing actions. The method is very convenient to use, can well clean the tooth parts on the lingual side, and can perform personalized cleaning on the different parts of the teeth. Better implementation of Bass method is achieved.
Finally, it should be noted that: the embodiments are only intended to illustrate the technical solution of the present invention, but not to limit it. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will appreciate that: the technical solutions of the embodiments can still be modified, or some of the technical features thereof can be equivalently replaced. Such modifications and substitutions do not depart from the spirit and scope of the embodiments of the present invention in its nature.
Number | Date | Country | Kind |
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201810386151.3 | Apr 2018 | CN | national |
This application is a Continuation of co-pending application Ser. No. 17/049,550, filed on Oct. 21, 2020, for which priority is claimed under 35 U.S.C. § 120; which claims priority of PCT Application No. PCT/CN2019/082554 filed on Apr. 12, 2019 under 35 U.S.C. § 119; and this application claims priority of Application No. 2018/10386151.3 filed in CN on Apr. 26, 2018 under 35 U.S.C. § 119, the entire contents of all of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | 17049550 | Oct 2020 | US |
Child | 18675413 | US |