BR112013005083B1 - BUCAL HYGIENE CABLE - Google Patents

Abstract

INSTRUMENT FOR ORAL TREATMENT THAT DETECTS STRENGTH. The present invention relates to an insert for an oral hygiene handle having a cavity. The insertion element has a charge element capable of rotating in relation to the compartment and an output source arranged in electromagnetic communication with the charge element, a power source in electrical communication with an output source that has a first and a second contact areas, and an indication element that forms an outward facing surface. When the load element rotates a predetermined amount, a first contact arm makes contact with a first contact area and / or a second contact arm makes contact with the second contact area, thus making the energy source supply energy to the output source, the output source providing electromagnetic energy to the load element, the load element transmitting the electromagnetic energy from the output source to the indicating element, and the load element, the element display and the coupling section are integral with each other.

Description

FIELD OF THE INVENTION

[0001] The present invention relates to a personal hygiene device, more particularly a personal hygiene device that includes a force indication system.

BACKGROUND OF THE INVENTION

[0002] The use of toothbrushes to clean a user's teeth has been known for a long time. During the brushing process, a user generally applies a force to the brush that is exerted against the teeth and gums by the cleaning elements of the toothbrush. A minimum level of force must be applied to remove plaque and debris; however, high levels of strength can have negative consequences for an individual's health. For example, problems such as irritation of the gums may occur, or over time, retraction of the gums or abrasion of the tooth enamel. Unfortunately, the presence of these problems can intensify a contributing factor, that is, an intense brushing force. As some users may realize that such problems can be caused by insufficient cleaning, in an effort to correct the problems users can apply even more intense force during brushing which, in turn, can cause more gum irritation and / or retraction gums or abrasion of tooth enamel.

[0003] To avoid or mitigate these problems, dental professionals can recommend the use of a soft bristle toothbrush. However, the use of a soft-bristled toothbrush does not exclude the application of intense brushing forces to the oral cavity. In addition, it is extremely difficult for an individual, during brushing, to determine the ideal strength required for cleaning. Although a user can apply a minimum level of force to achieve cleaning, it is difficult to perceive the level at which the force is excessively high. In addition, studies have shown that the cleaning capacity of a toothbrush can, in fact, be reduced if the brushing strength is increased to an excessively high level.

[0004] Other recommended solutions may be to apply less force during brushing. However, if very weak force is applied during brushing, the cleaning efficiency of the toothbrush can often be reduced. Additionally, similarly to intense brushing forces, the individual may find it difficult to determine when brushing forces are too weak.

[0005] Consequently, there is a need for a personal hygiene implement that signals to the user when an excessively high brushing force is being applied.

SUMMARY OF THE INVENTION

[0006] An oral hygiene handle containing a cavity and an insert element disposed within the cavity is described in the present invention. The insertion element comprises a load element capable of rotating with respect to the compartment; an output source arranged in electromagnetic communication with the load element, the output source having a first contact arm and a second contact arm; a power source in electrical communication with the output source, the power source having a first contact area and a second contact area; a coupling section capable of receiving an accessory for oral treatment; and an indicating element forming a surface facing away from the oral hygiene implement, and when the load element rotates a predetermined amount, the first contact arm makes contact with a first contact area and / or the second contact arm makes contact with a second contact area thus causing the energy source to supply energy to the output source, the output source providing electromagnetic energy to the charging element, the charging element transmitting the electromagnetic energy of the output source for the indicating element, and the loading element, the indicating element and the coupling section are integral with each other.

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] Figure 1 is an elevation view showing a left side of an oral hygiene implement, for example, a toothbrush, constructed in accordance with the present invention.

[0008] Figure 2A is a plan view showing an element for inserting the toothbrush in Figure 1.

[0009] Figure 2B is a plan view of the insertion element of figure 1 with an optional removable head / neck assembly.

[00010] Figure 3A is a close-up view showing an approximate portion of the insertion element of figure 2B.

[00011] Figure 3B is a close-up view showing the approximate portion of the insertion element of figure 2B with a loading element removed for ease of explanation.

[00012] Figure 3C is a close-up view showing the approximate portion of the insertion element of figure 2B with a support removed for ease of explanation.

[00013] Figure 4A is a close view showing a first face of a distal portion of the insertion element of figure 2B.

[00014] Figure 4B is a close view showing a second face of the distal portion of the insertion element of figure 2B.

[00015] Figure 4C is a close view showing a cross section of the distal portion of the insertion element of figure 2B taken along line 4C-4C.

[00016] Figures 5A to 5D are seen close up showing various modalities of load element receptacles from an electromagnetic source.

[00017] Figure 5E is a close view showing another modality of the charge element where the electromagnetic source is not disposed within a receptacle.

[00018] Figure 6A is a close view showing the proximal end of the insertion element of figure 2B with some features removed for ease of explanation.

[00019] Figure 6B is a partial cross-sectional view of the proximal end of the insertion element shown in figure 6A taken along line 6B-6B.

[00020] Figure 6C is a close view showing the proximal end of the insertion element of figure 6A with some features removed for ease of explanation.

[00021] Figures 7A to 7E are seen in cross section showing various modalities of an indicating element and the reflective core shown in figure 6C, each taken along line 7-7.

[00022] Figure 8A is a close view of a proximal end showing another embodiment of an insertion element.

[00023] Figure 8B is a close view of a distal end of the insertion element of figure 8A.

[00024] Figure 9 is a partial cross-sectional view showing another embodiment of an insert element of the present invention.

[00025] Figures 10A to 10C show a neck and head assembly for use with the present invention.

[00026] Figures 11A to 11D are seen in cross section of exemplary LEDs that are suitable for use with the oral hygiene implement of the present invention.

[00027] Figure 12 is a side view showing a toothbrush constructed in accordance with the present invention.

[00028] Figure 13 shows a sample of a toothbrush attached to a test frame.

[00029] Figure 14 is a cross-sectional view showing the toothbrush sample of Figure 13 and a pull block on a toothbrush head of the toothbrush sample.

[00030] Figure 15 is a close view showing the toothbrush sample in Figure 13 and the pull block on the toothbrush head of the toothbrush sample.

[00031] Figure 16 is a close view showing a force indicator attached to the pull block of figures 14 and 15.

[00032] Figure 17A is a cross-sectional view showing another embodiment of an oral hygiene implement constructed in accordance with the present invention.

[00033] Figure 17B is a close view showing the cross section of the oral hygiene implement in figure 17A.

DETAILED DESCRIPTION OF THE INVENTION Definitions:

[00034] The following text provides a broad description of numerous different embodiments of the present invention. The description is intended to be interpreted as merely exemplary and does not describe all possible modalities, as this would be impractical, if not impossible, and it should be understood that any resource, characteristic, component, composition, ingredient, dosage, product, stage or The methodology described here can be totally or partially erased, combined with, or replaced by, any other resource, characteristic, component, composition, ingredient, product, stage or methodology described here. Numerous alternative modalities could be implemented, using the current technology or the technology developed after the date of filing this patent, which would still be within the scope of the claims.

[00035] It should also be understood that unless a term is expressly defined in this patent using the phrase "For use in the present invention, the term '' means ...", or a similar phrase, there is no intention to limit the meaning of that term, either expressly or by implication, beyond its common or usual meaning, and that term should not be construed as having a limited scope based on any statement made in any section of this patent (except the language claims). No term is intended to be essential to the present invention, except when so stated. To the extent that any term recited in the claims, at the end of this patent, is mentioned in this patent in a manner consistent with a single meaning, this is done only for the sake of clarity so as not to confuse the reader, and there is no intention that this claim term be limited, by implication or otherwise, to that one. Finally, unless an element of the claim is defined by the mention of the word "means" and a function, without mention of any structure, there is no intention that the scope of any claim element will be interpreted based on the application of the 35 USC § 112, sixth paragraph.

[00036] For use in the present invention, the term "personal hygiene implement" refers to any implement that can be used for personal hygiene purposes. Some suitable examples include toothbrushes, manual or equipped with a motor; razors or shavers, manual or equipped with a motor; shavers, manual or equipped with a motor; sideboards, etc.

[00037] For use in the present invention, the term "oral hygiene implement" refers to any device that can be used for oral hygiene purposes. Some suitable examples of such devices include toothbrushes (manual and equipped with a motor), dental floss applicators (manual and equipped with a motor), mouthwashers (water picks), and the like.

Description:

[00038] For ease of explanation, the implement of oral hygiene described hereinafter must be a manual toothbrush; however, as stated earlier, an oral hygiene implement constructed in accordance with the present invention is not limited to a manual toothbrush construction. In addition, the modalities described hereinafter are also applicable to razors, razors or shavers, other personal hygiene implements, or the like.

[00039] As shown in figure 1, a toothbrush 10 comprises a handle 12, a head 14 and a neck 16 extending between the handle 12 and the head 14. A field of contact elements 20 extends from of a first surface 14A of the head 14. The cable 12 may comprise a distal end 80 and a proximal end 90. A tongue cleaner, soft tissue cleaner, massage element, or the like, may be disposed on a second surface 14B of the head 14. The field of contact elements 20, tongue cleaners, soft tissue cleaners, massage elements, or the like, are discussed later in this document.

[00040] An indicating element 30 can be arranged between the cable 12 and the neck 16 adjacent to the proximal end 90. The indicating element 30 can provide a user with a visible signal for at least one of a plurality of conditions. For example, the visible signal can be provided when a user has brushed for an appropriate period of time, for example, two minutes, when the toothbrush needs to be replaced and / or when the user is applying excessive force during brushing . Additional conditions for which a signal can be provided are discussed later in this document.

[00041] The indicating element 30 can be arranged at any suitable location on the toothbrush 10. For example, in some embodiments, the indicating element 30 can encircle the neck 16 or it can encircle the handle 12. As another example, the indicating element 30 may surround a portion of the cable 12 and / or a portion of the neck 16. As yet another example, the indicating element 30 may be arranged on a surface facing the rear 40B of the cable 12 and / or the neck 16. As yet another example, the indicating element 30 can be arranged on a surface facing the front part 40A of the cable 12 and / or the neck 16.

[00042] With reference to figures 1 to 2B, as shown, the indicating element 30 can be positioned between a first sealing element 70 and a second sealing element 75. The first sealing element 70 can be configured to eliminate or reduce the likelihood of moisture entering the cable 12. For example, the first sealing element 70 can have a first portion 70A that seals an inner surface of the cable 12. Additionally, the first sealing element 70 can have a second portion 70B that seals sealing a proximal surface 30A of the indicating element 30 and sealingly engages an interface between the cable 12 and the first sealing element 70. As an additional example, the second sealing element 75 can sealingly engage a distal surface 30B of the sealing element indication 30 and sealingly engage the neck 16.

[00043] Arrangements are contemplated in which the head 14 is replaceable, for example, removably attached to the neck 16. In such modalities, after the head 14 has been used for a particular period of time, for example, three months, the head 14 can be replaced with a new one. Similarly, modalities are contemplated in which the head 14 and the neck 16 are integrally formed, for example, as a unit. In such embodiments, the neck 16 can be removably attached to the cable 12 and can be replaced after a period of time, for example, three months. Additionally, in such embodiments, the neck 16 may have a receiving section that is configured to receive an engagement section 316. As shown in figure 3, the engagement section 316 may comprise holders that act as snap-fit features which eliminate or reduce the likelihood that the neck 16 can be removed during normal brushing by the user.

[00044] With reference to figures 2A and 2B, an insertion element 200 can be arranged inside the cable 12 (shown in figure 1). The insertion element 200 can comprise a first support 215 and a second support 216. The insertion element 200 can additionally comprise a charging element 230, a power source 240 and an electromagnetic source 250, for example, an LED. The first support 215 and the second support 216 can provide support for the load element 230, the power source 240 and the electromagnetic source 250 within the cable 12 (shown in figure 1). For example, the first support 215 and the second support 216 can be configured to engage structures within the cable 12 (shown in figure 1) to lock the insert 200 in place during use. In addition, the first support 215, the second support 216 and the structure inside the cable 12 (shown in figure 1) can comprise holders for locking the insert 200 inside the cable 12 (shown in figure 1). In some embodiments, in addition to the supports and / or holders, or independently of them, a fixing element, for example, a screw, can be used at the distal end 80 (shown in figure 1) to fix the insertion element 200 in the cable 12 (shown in figure 1). Other suitable fastening elements are contemplated, for example, adhesive, Velcro ™, the like, or combinations thereof.

[00045] As shown, in some embodiments, the load element 230 can be pivotally attached to the first support 216 and / or the second support 215 by means of springs 280 and / or 290. With reference to figures 3A to 3C, springs 280 and 290 can comprise torsion bars. The springs 280 and 290 must be constructed in such a way that the articulation of the load element 230 does not cause plastic deformation in springs 280 and 290. Instead, the articulation movement of the load element 230 should only cause the elastic deformation of the springs 280 and 290.

[00046] Springs 280 and 290 must be designed to avoid fatigue failure. The variables that can affect fatigue failure and elastic deformation are the choice of material, the sizing of the springs and the angular displacement of springs 280 and 290.

[00047] Springs 280 and 290 can comprise any suitable size. For example, in some embodiments, springs 280 and 290 may comprise an area in cross section that is greater than about 3 mm2 to about 50 mm2, or any individual number within that range. In some embodiments, the springs may comprise an area in cross section between about 10 mm2 and about 20 mm2. In yet other embodiments, the springs may comprise an area in cross section that is greater than about 3 mm2, greater than about 5 mm2, greater than about 7 mm2, greater than about 10 mm2, greater than about 15 mm2 , greater than about 17 mm2, greater than about 20 mm2, greater than about 25 mm2, greater than about 30 mm2, greater than about 35 mm2, greater than about 40 mm2, greater than about 45 mm2, and / or less than about 50 mm2, less than about 45 mm2, less than about 40 mm2, less than about 35 mm2, less than about 30 mm2, less than about 25 mm2, less than about 20 mm2, less than about 15 mm2, less than about 12 mm2, less than about 10 mm2, less than about 7 mm2, less than about 5 mm2, or any ranges within the numbers shown. However, it is worth noting that if the cross-sectional area of springs 280 and 290 is too large, then the load element 230 will tend to flex contrary to the joint.

[00048] Springs 280 and 290 can be configured to influence the response force. An example of the influence of the response force is the change in the cross-sectional area of the springs 280 and / or 290. Other examples of influence of the response force include the choice of material and the length of the spring.

[00049] In some embodiments, the load element 230 can be created separately from the springs 280 and / or 290 and later fixed to them. In such embodiments, the spring 280 can be configured so that a first surface 230A of the load element 230 engages a first engaging surface 280A of the spring 280 so that the first surface 230A does not rotate with respect to the first engaging surface 280A. Similarly, spring 290 can be configured so that a second surface 230B does not rotate with respect to a first engaging surface 290A of spring 290.

[00050] For example, the first engaging surface 280A may comprise a detent that engages with a complementary depression in the first surface 230A. As another example, the first engaging surface 280A may comprise a complementary depression which engages a holder which is comprised of the first surface 230A. As yet another example, the first engagement surface 280A and the first surface 230A may comprise a holder and a depression and be configured so that the holder of the first surface 230A engages in the depression of the first engagement surface 280A and so that the holder the first engaging surface 280A engages with the depression of the first engaging surface 230A. The second surface 230B and the first engaging surface 290A can be configured in a similar manner. Arrangements are contemplated in which a plurality of complementary holders and depressions can be used on the first surface 230A, the second surface 230B and / or the first surfaces of coupling 280A and 290A.

[00051] In some embodiments, the loading element 230 can be integrally formed with springs 280 and / or 290. In such embodiments, springs 280 and / or 290 can be configured so that a first surface facing inward 215A of the the first support 215 engages a second engaging surface 280B of the spring 280 so that the first inward facing surface 215A does not rotate with respect to the second engaging surface 280B. Similarly, spring 290 can be configured so that a second inward facing surface 216A does not rotate with respect to a second engaging surface 290B of spring 290. The detectors and depressions described so far can be used to eliminate or eliminate least reduce the probability of rotation.

[00052] As mentioned so far, the length of springs 280 and / or 290 can affect the response force provided by springs 280 and / or 290. A length 1580 of spring 280 is defined by the distance between the first engaging surface 280A and the second engaging surface 280B. The length 1580 of the spring 280 can be affected by the material selected for the spring. Additional factors include aesthetics as well as the ability to grasp by a user. Length 1580 can be any suitable length. In some embodiments, the length 1580 may be greater than about 1 mm, greater than about 1.5 mm, greater than about 2.0 mm, greater than about 2.5 mm, greater than about 3.0 mm, greater than about 3.5 mm, greater than about 4.0 mm, greater than about 4.5 mm, greater than about 5.0 mm, greater than about 5.5 mm, greater than about 6 mm, greater than about 6.5 mm, greater than about 7 mm, greater than about 7.5 mm, and / or equal to about 8.0 mm, less than about 7.5 mm, less than about 7.0 mm, less than about 6.5 mm, less than about 6.0 mm, less than about 5.5 mm, less than about 5.0 mm, less than about 4 , 5 mm, less than about 4.0 mm, less than about 3.5 mm, less than about 3.0 mm, less than about 2.5 mm, less than about 2.0 mm, less than about 1.5 mm, or any numbers or bands within or including the above values. The spring 290 can be similarly constructed.

[00053] For ease of assembly to be contemplated, the modalities in which the load element 230 is formed, integrally, with the first support 215, the second support 216 and / or the springs 280 and 290. In some modalities, the loading element 230 can be integrally formed with the first support 215, the second support 216, the springs 280 and 290 and / or the engagement portion 316.

[00054] Referring to figure 4A, a second portion of the insertion element 200 is shown. The charging element 230 may comprise a first contact arm 265A and a second contact arm 265B that can provide electrical communication between the electromagnetic source 250 and the power supply (s) 240. Modes in which only one power source is used are contemplated. In such embodiments, only one contact arm may be required.

[00055] With reference to figures 4A to 4C, the load element 230 may comprise a lock 280 which is configured to engage an internal surface of the cable 12 (shown in figure 1). In operation, when sufficient force is applied to the cleaning element field 20 (shown in figure 1), the load element 230 rotates in relation to the first support 215 and / or the second support 216. If the applied force is excessive, then, the load element 230 rotates so that the first contact arm 265A and the second contact arm 265B establish the electrical communication between the power source (s) 240 and the electromagnetic source 250. Like the contact 265A and 265B are in contact with their respective power source (s) 240, an additional applied force tends to cause deflection in the load element 230. This deflection in the load element 230 can lead to plastic deformation load element 230 and / or contact arms 265A and / or 265B. In an effort to reduce the likelihood of plastic deformation, the locking element 280 can be arranged on the load element 230. The locking element 280 can be integrally formed with the load element 230, or the locking element 280 can be a separate element that is attached to the load element 230.

[00056] The blocking element 280 can be positioned at any suitable location along the loading element 230. Additional modalities are contemplated where the loading element 230 comprises a plurality of blocking elements. Additionally, modalities are contemplated in which the cable comprises a blocking element that protrudes towards the load element 230 from an internal surface of the cable. Arrangements are contemplated in which a plurality of blocking elements protrude from an internal surface of the cable. Also contemplated are modalities in which a plurality of blocking elements are used and at least one protrudes from the load element 230 and at least one protrudes from the internal surface of the cable.

[00057] With reference to figure 4C, the blocking element 280 can be of any suitable size. For example, the blocking element 280 may have a height 281 that is greater than about 1 mm, greater than about 2 mm, greater than about 3 mm or any number within the described ranges, or any range including the described values. The locking element 280 must be designed to withstand the applied brushing forces, as well as forces that exceed the upper limit of the force value. For example, blocking element 280 can be designed to withstand an applied load greater than about 4 Newtons, greater than about 5 Newtons, greater than about 6 Newtons, greater than about 7 Newtons, greater than about 8 Newtons, greater than 9Newtons, less than 9Newtons, less than 8Newtons, less than 7Newtons, less than 6Newtons, less than 5Newtons, or any number within the ranges described, or any range including the values described.

[00058] With reference to figures 2A and 4C, as shown, the electromagnetic source 250 can be arranged on the load element 230. When an excessive force is applied, the electromagnetic source 250 can be activated, thus providing electromagnetic energy for the element of load 230. In some embodiments, the load element 230 can transmit the electromagnetic energy from the electromagnetic source 250 to the indicating element 30. In such embodiments, the load element 230 can be a light tube, a light guide, a optical fiber, or the like. The material selected for the loading element 230 can be clear, transparent, translucent or combinations thereof. Some suitable examples for the loading element 230 include glass, polymethyl methacrylate, polycarbonate, copolyester, polypropylene, polyethylene terephthalate, combinations thereof, for example, polyester and polycarbonate, or the like.

[00059] In some embodiments, the display element 30 and the loading element 230 can form a unit. For example, the loading element 230 and the indicating element 30 can be constructed entirely from a first material during an injection molding process. In some embodiments, the loading element 230 can be a separate part which is later connected to the indicating element 30. In some embodiments, the indicating element 30, the loading element 230, the engaging section 316, the first support 215 and / or the second support 216 can be formed integrally. In some embodiments, the indicating element 30, the loading element 230 and / or the engaging section 316 can be integrally formed and subsequently attached to the first support 215 and / or the second support 216. A benefit of such modalities is the number reduced number of components required for the brush, which can reduce the cost and / or the assembly time.

[00060] The charging element 230 can transmit electromagnetic energy, for example, visible light, to the display element 30 by means of internal reflection or external reflection. External reflections are reflections where the light originates from a material with a low refractive index (such as air) and is reflected from a material with a higher refractive index (such as aluminum or silver). A common household mirror works by external reflection.

[00061] Internal reflections are reflections where the light originates from a material with a higher refractive index (such as polycarbonate) and is reflected from a material with a lower refractive index (such as air, vacuum or water). Fiber optic technology works based on the principle of internal reflections.

[00062] The refractive index is an optical attribute of any material that measures the tendency of light to refract, or tilt, when passing through the material. Even materials that do not conduct light (such as aluminum) have refractive indices.

[00063] Typically, external reflections are most efficient when the angle of incidence of light is close to normal (that is, light strikes perpendicular to the surface) and degrade as the angle of incidence increases (that is, light focuses on a surface at a steep angle). In contrast, internal reflections are the most efficient at high angles of incidence and do not reflect at shallow angles, for example, normal to the surface. To perform internal reflection, the angle of incidence must be greater than the critical angle. The critical angle is the angle below which the light stops reflecting between a pair of materials.

[00064] With reference again to figures 1 and 2A, for the modalities of the present invention that use external reflection, a metallic sheet or some other highly reflective material can be used inside the cable 12. The highly reflective material, for example, metallic sheet , may be arranged on the inner surface of the cable 12. In other embodiments, the highly reflective material, for example, foil, can be wrapped around the load element 230. A disadvantage of such modalities is that additional steps may be necessary of manufacturing to supply the highly reflective material to the appropriate location (s).

[00065] For modalities that use internal reflection, a material can be selected that has a high refractive index, for example, above 1.0. For example, the material selected for the loading element 230 may comprise a refractive index greater than about 1.4, greater than about 1.5, greater than about 1.6, and / or less than about 1 , 7, less than about 1.6, less than about 1.5, or any number within the described ranges, or any range including the described values. In some embodiments, the material selected for the load element 230 has a refractive index between about 1.4 and about 1.6.

[00066] With reference to figures 2A to 2B, in such embodiments, an external surface 429 of the load element 230 can be polished. The polished outer surface 429 of the load element 230 can reduce the amount of light lost from the load element 230.

[00067] With reference to figures 2A and 5A-5E, in some embodiments, the charging element 230 may comprise a receptacle 553A, 553B, 553C, 553D for receiving the electromagnetic source 250. The receptacle 553A, 553B, 553C, 553D can be arranged on an end 555A, 555B, 555C, 555D of the load element 230. A benefit of implementing the 553A, 553B, 553C, 553D end on the 555A, 555B, 555C, 555D end of the load element 230 is that during manufacture , the electromagnetic source 250 can be inserted into the receptacle 553A, 553B, 553C, 553D, thereby reducing the chance of misalignment of the electromagnetic source 250 in relation to the charging element 230. This can help to reduce the amount of light lost between the source electromagnetic 250 and the charging element 230.

[00068] As previously stated, to carry out internal reflection, the incident light must be above the critical angle. The angle at which the light falls on the load element 230 can be affected by the distribution angle (discussed hereinafter in this document) of the electromagnetic source 250. For output sources that have a small distribution angle, the design of the receptacle 553A, for example, sides 557A and 557B perpendicular to face 557C, may be sufficient to capture most of the light emitted by the electromagnetic source 250 for internal reflection. However, incident light above the critical angle will generally not be reflected internally. Consequently, sides 559A, 559B and / or face 559C of housing 553B can be configured to increase the amount of light above the critical angle. As shown, face 559C may comprise an angle to increase the angle of incidence of electromagnetic energy provided by electromagnetic source 450. As another example, receptacle 553C may comprise sides 551A, 551B and a face 551C that has an arcuate shape, for example example, like a lens. As yet another example, receptacle 553D may comprise sides 549A, 549B and face 549C. The sides 549A and / or 549B can taper towards face 549C. Combinations of these features are also contemplated. For example, a receptacle may comprise conical sides tapering towards or away from the face, and / or may comprise an angled face, an arcuate face, for example, a lens, or the like.

[00069] With reference to figure 5E, in some embodiments, a load element 230 can be configured with a flat surface at one end 555. In such embodiments, the electromagnetic source 250, for example, LED, can be positioned at a distance 560 away from end 555. In an effort to reduce the amount of light lost from output source 250, distance B (560) should, in general, be within the guidelines presented below.

[00070] Where α is the half angle α according to the manufacturer's specifications for an electromagnetic source, and where A (567) is a projection section on the load element 230. The projection section 567 is the distance in a straight line between the midpoint of the output source 250 projected onto the load element 230 to an edge 569 of the load element 230.

[00071] For modalities that use internal reflection, the distribution angle of the electromagnetic source 250, for example, LED, must be considered. If the distribution angle is too wide, a portion of the light supplied to the load element 230 may not be reflected internally and will instead escape from the load element 230. Any suitable distribution angle can be used. Some examples of suitable distribution angles include greater than about 0 degrees, greater than about 1 degree, greater than about 2 degrees, greater than about 5 degrees, greater than about 6 degrees, greater than about 8 degrees, greater than about 10 degrees, greater than about 12 degrees, greater than about 14 degrees, greater than about 16 degrees, greater than about 18 degrees, greater than about 20 degrees, greater than about 22 degrees, and / or less than about 22 degrees, less than about 20 degrees, less than about 18 degrees, less than about 16 degrees, less than about 14 degrees, less than about 12 degrees, less than about 10 degrees , less than about 8 degrees, or any number within the described ranges, or any range including the described values.

[00072] As stated previously, the load element 230 can transmit electromagnetic energy supplied by the electromagnetic source 250 to the indicating element 30. In an effort to reduce the amount of energy lost through the engagement section 316, a reflective core 661 ( shown in figure 6) can be used. For the modalities in which the neck 16 (shown in figure 1) and / or the head 14 (shown in figure 1) are not separable, a reflective core can be used on the neck 16 and / or the head 14.

[00073] With reference to figures 1 and 6A to 6C, as shown, the reflective core 661 can be arranged on the indicating element 30 and extends to the engagement section 316. The reflective core 661 can reduce the amount of light that is lost through the engagement section 316 and into the neck and / or brush head. Additionally, the reflective core 661 can assist in the distribution of light through the indicating element 30 to a periphery 630 of the indicating element 30. In addition, in some embodiments, the reflective core 661 can be configured to assist in providing light to the first element seal 70 and / or the second seal element 75. In embodiments in which the first seal element 70 and / or the second seal element 75 are transparent or translucent, a unique visual effect can be created.

[00074] The reflective core 661 may comprise a polished area 667 having a face 668. The polished area 667 of the reflective core 661 is a portion of the reflective core 661 arranged within the indicating element 30. The rest of the reflective core 461 can be polished, but not necessarily. The polished area 667 can be configured to redirect the light transmitted through the load element 230 to the indicating element 30, the first sealing element 70 and / or the second sealing element 75.

[00075] In cases where the indicating element 30 is a ring, for example, the outer periphery 630 is circular, the polished area 667 can be configured in the form of a cone (see figure 7A). As shown in figure 7B, in cases where the indicating element 30 comprises a ring, for example, the outer periphery 630 is circular, the polished area 667B can comprise a face 668B having multiple sides. As shown in figure 7C, an indicating element 30C can comprise an outer periphery 630C having multiple sides. And, a polished area 667C can be configured in the form of a cone. As shown in figure 7D, an indication element 30D may comprise a periphery 630D having multiple sides. And, a polished area 667D may comprise a face 668D that has multiple sides. The sides of the face 668D can be substantially parallel to the sides of the sides of the periphery 630D of the indicating element 30D. As shown in figure 7E, an indicating element 30E can comprise a periphery 630D having multiple sides, and a polished area 667E can comprise a face 668E having multiple sides. As shown, the sides of the face 668E can be arranged non-parallel to the side of the outer periphery 630E of the indicating element 30E. It is believed that such arrangements may produce a different visual effect than that of a polished area 667, 667C which is tapered.

[00076] In some embodiments in which the indicating element does not extend 360 degrees around the brush to form an external surface of the brush, the polished area can be configured to distribute the transmitted light to a portion of the indicating element that is visible for the user. For example, in cases where the indicating element extends 90 degrees around the brush, the polished area can be configured as a portion of a cone that distributes light to the indicating element.

[00077] With reference to figure 6C, the reflective core 661, as shown, can be a recess that remains empty in the final product. In some embodiments, the reflective core 661 can be partially filled with a material. In cases where the reflective core 661 is partially filled, an air gap can be provided between the filler material and the polished area 667. The existence of this air gap can ensure that the internal reflection is maintained inside the indicating element . In some embodiments, the reflective core 661 can be completely filled with a material that has a lower refractive index than the index of the material that forms the reflective core 661.

[00078] It is believed that without the 661 reflective core, less than about 10 percent of the light provided by the electromagnetic source would be emitted by the indicating element. And, it is believed that with the reflective core 661, an amount of about 90 percent or more of the light provided by the electromagnetic source would be emitted by the indicating element, the first sealing element 70 and / or the second sealing element 75. In In some embodiments, the light emitted by the indicating element is greater than about 10 percent than the light provided by the electromagnetic source, greater than about 20 percent, greater than about 30 greater than about 50 greater than about 70 greater than about 90 percent, greater than percent, greater than percent, greater than percent, less than about 40 percent, about 60 percent, about 80 percent, less than about 90 percent, less than about 70 percent, less than about 50 percent, less than about 80 percent, less than about 60 percent, less than about 40 percent, less than about 30 percent, less than about 20 percent, or any number within the ranges described, or any range including the the values described. A test method for measuring the efficiency of light emission is discussed hereinafter.

[00079] In some embodiments, as shown in figure 8A, an insertion element 800 may comprise a loading element 830 that can be pivotally attached to a first support 815 and / or a second support 816 similar to the insertion element 200. The insertion element 800 may further comprise an indicating element, a power source and an electromagnetic source as described here and can be constructed in a similar manner to the insertion element 200, except as described below.

[00080] The load element 830 can be pivotally attached to the first support 815 and / or the second support 816 by means of a pivot support 870 instead of springs, for example springs 280 and 290, as discussed until the moment. The pivot support 870 can be fixedly connected to the first support 815 and / or the second support 816 so that the pivot support 870 cannot rotate in relation to the first support 815 and / or the second support 816. In such embodiments, the pivot support 870 can be swiveled to the load element 830 so that the load element 830 can rotate in relation to the pivot support 870. Other configurations are also contemplated. For example, the pivot support 870 can be attached to the load element 830 so that the pivot support 870 cannot rotate in relation to the load element 830. In such embodiments, the pivot support 870 can be pivoted in relation to the first support 815 and the second support 816.

[00081] For modes in which the pivot support 870 is pivotally coupled to the first support 815 and the second support 816, the pivot support 870 can be formed integrally with the load element 830. For modalities in which the support- pivot 870 is pivotally coupled to the load element 830, the pivot support 870 can be integrally formed with the first support 815 and / or the second support 816.

[00082] For such modalities, the pivot support 870 can be configured to offer little or no resistance to the rotation of the load element 830. Consequently, a resistance element can be used. As shown in figure 8B, the loading element 830 can comprise a blocking element 880 similar to the blocking element 280 discussed so far in relation to the insertion element 200. In addition, the loading element 830 can comprise a resilient element 890, for example , a spring. The resilient element 890 can be configured so that a load applied to the field of contact elements causes compression of the resilient element 290. Alternatively, the resilient element 890 can be configured so that a load applied to the field of contact elements causes the elongation of the resilient element 290. In yet other embodiments, more than one resilient element can be used so that an applied load causes the elongation of one resilient element and the compression of another.

[00083] In some embodiments, as shown in figure 9, an insertion element 900 can comprise a load element 930 which is hingedly attached to a cable 912. The insertion element 900 can further comprise a first sealing element 970 and a second sealing element 975 which can be configured as discussed in relation to the first sealing element 70 and the second sealing element 75. Additionally, the insert element 900 can comprise an engaging portion 916 which can be configured similarly to the portion latch 316. The insert 900 can further comprise an indication element 1930 for providing visible signals to a user. In some embodiments, the engaging portion 916, the indicating element 1930 and / or the loading element 930 can be integrally formed.

[00084] The charging element 930 may comprise a receptacle as described so far that can accommodate an electromagnetic source 950, for example, LED. The electromagnetic source 950 may comprise contacts 965A and 965B that can provide electrical communication between the electromagnetic source 950 and power supply 940 when excessive force is applied by the user.

[00085] Similar to the configuration shown in figures 8A and 8B, the load element 930 can be pivotally mounted by means of a pivot support that provides little or no resistance to rotation of the load element 930. As shown, a contact , for example 965B, can be used as the spring that provides resistance to the movement of the load element 930. For example, as shown, when a force is applied to the field of contact elements causing the load element 930 to rotate With respect to cable 912, contact 965B may tend to move towards a contact base 967. In some embodiments, a support base 981 integral with the load element 930 can be used to properly flex contact 965B when excessive force is applied.

[00086] The load elements 830 and 930 can be configured in a similar way to the load element 230 described so far. For example, the charging elements 830 and 930 can transmit electromagnetic energy to their respective display elements by means of internal reflection or external reflection. In addition, insertion elements 800 and 900 can be constructed similarly to insertion element 200. For example, their respective indicating elements can comprise a reflective core as described here.

[00087] In some embodiments, as shown in figure 17A, a toothbrush may comprise an insertion element 1700 that has a load element 1730 that is pivotally attached to a support 1715. The pivot connection between the load 1730 and support 1715 can be configured so that there is little resistance, if any, to movement. The load element 1730 can be constructed in a similar manner to the load elements 230, 830 and 930. As shown, the load element 1730 can comprise an indicating element 2730. The indicating element 2730 can comprise an elastomeric material that is overmolded by injection on the loading element 1730. In addition, a 1770 sealing element can be integrally formed with the indicating element 2730. The 1770 sealing element can be engaged on an internal surface of a cable to prevent or reduce the likelihood of water ingress and / or other contaminants in the cable cavity.

[00088] In such embodiments, the display element 2730 may comprise a translucent or transparent material to allow electromagnetic energy from a 1750 electromagnetic source to be supplied to the user. In addition, unique color combinations can be created with the use of a colored material for the display element 2730. For example, the electromagnetic source 1750 can provide an electromagnetic output of a first color, while the display element 2730 can comprise a second The first color can be different from the second color, for example blue and yellow, respectively. As another example, the display element 2730 can comprise a complementary color. The display element 2730 can be of a first color and the electromagnetic source can emit electromagnetic energy which basically comprises the first color, for example, red and red.

[00089] In operation, the load element 1730 rotates in relation to the support 1715 when an applied load 1751 exceeds a certain limit. As shown, a resilient element 1790 can be positioned between a first contact 1765A and the load element 1730. The resilient element 1790 can be dimensioned properly so that the load element 1730 does not show articulated movement in relation to the support until a first limit force is applied. For example, in some embodiments, the resilient element 1790 can be applied to provide the load element with a pre-tension of about 3.2 Newtons. In such modalities, the load element 1730 would not show articulated movement in relation to the support 1715 until the applied force 1751 exceeded about 3.2 Newtons. When the applied force 1751 exceeds the first limit force, the load element 1730 rotates relative to the support 1715. For example, if the applied force 1751 is equal to or exceeds about 5 Newtons, then the load element 1730 will move one second contact 1765B in contact with the first contact 1765A. The first contact 1765A and the second contact 1765B can be in electrical communication with a power supply 1740 so that when the first contact 1765A and the second contact 1765B are in contact, a supply circuit for the electromagnetic output 1750 is energized.

[00090] The second contact 1765B can be configured to offer little or no resistance to the movement of the load element 1730. Alternatively, the second contact 1765B can be configured to offer some resistance to this movement in addition to the resilient element 1790.

[00091] Similar to the load elements discussed so far, the load element 1730 can comprise a reflective core 1761. The reflective core 1761 can be constructed in a similar way to the reflective cores discussed here. Similarly, the loading element 1730 may comprise a locking element as described so far in relation to figures 8A and 8B.

[00092] With reference to figures 17A and 17B, a distance 1741 between a first surface 1730A of the load element 1730 and an internal surface 1766 of the first contact 1765A can be any suitable distance. For example, the distance 1741 can be greater than about 0.3 mm to about 1.3 mm. In some embodiments, the distance 1741 can be greater than about 0.3 mm, greater than about 0.4 mm, greater than about 0.5 mm, greater than about 0.6 mm, greater than about 0 , 7 mm, greater than about 0.8 mm, greater than about 0.9 mm, greater than about 1.0 mm, greater than about 1.1 mm, greater than about 1.2 mm, less than about 1.3 mm, less than about 1.2 mm, less than about 1.1 mm, less than about 1.0 mm, less than about 0.9 mm, less than about 0, 8 mm, less than about 0.7 mm, less than about 0.6 mm, less than about 0.5 mm, less than about 0.4 mm or any number within the ranges described, or any range including the values described. In some embodiments, the distance 1741 is about 0.8 mm.

[00093] The pre-tensioning of the load element 1730 so that the pivoting movement does not start before an applied force 1751 of about 3.2 Newtons is important from the point of view of tolerance in addition to the distance 1741. For example , if it is necessary to provide the user with an indication of an excessive applied force in relation to the applied force 1751 of about 5 Newtons, the load element 1730 can be pre-tensioned by about 3.2 Newtons, and the distance 1741 between the first surface 1730A and internal surface 1766 may be about 0.7 mm. In such modalities, the distance 1741 of 0.7 mm corresponds to 1.8 Newtons or 2.5 N / mm. In contrast, without a preload, the 1741 distance of 0.7 mm corresponds to 5 Newtons or 7.1 N / mm. For both examples, a tolerance of +/- 0.2 mm can lead to variations in the force indication. However, for the first example, a tolerance of +0.2 mm for distance 1741 means an indication of an excessively high applied force at around 5.5 Newtons. For the second example, a tolerance of +0.2 mm means an indication of about 6.4 Newtons. For a tolerance of -0.2 mm for distance 1741 in the first example with a preload of 3.2 N, the indication of an excessively high applied force would occur at an applied force of about 4.5 Newtons. In the second example, a tolerance of -0.2 mm for the distance 1741 in the second example without preload, the indication of an excessively high applied force would occur at about 3.55 Newtons. Therefore, preload can be beneficial when trying to reduce variations in the strength indication based on tolerance.

[00094] The amount of preload can be any suitable force. For example, in some embodiments, the preload can be greater than about 2 Newtons, greater than about 3 N, greater than about 3.2 N, greater than about 3.4 N, greater than about 3 , 6 N, greater than about 3.8 N, greater than about 4.0 N, greater than about 4.2 N, greater than about 4.4 N, greater than about 4.6 N, greater than about 4.8 N, less than about 5 N, less than about 4.8 N, less than about 4.6 N, less than about 4.4 N, less than about 4.2 N , less than about 4.0 N, less than about 3.8 N, less than about 3.6 N, less than about 3.4 N, or any number within the ranges described, or any range including those described values. In some embodiments, the preload is about 4 N.

[00095] In some modalities, the variation based on tolerance is less than about 20 percent of the indication value. For example, if the value of the indication is about 5 Newtons, the tolerance-based variation will be less than about 1 Newton. In some embodiments, the tolerance-based variation is less than about 15 percent of the indication value, less than about 10 percent of the indication value, less than about 5 percent of the indication value, or any number within of the described ranges, or any range including the described values.

[00096] At least one benefit of the modalities shown in figures 8A, 8B, 9 and 17A to 17B is the ability to customize insertion elements 800, 900 and 1700. As a resilient element, for example, springs 890, 1790 and the contact 965B, are used as the main sources or resistance to movement of the respective load elements 830, 930, 1730, the insertion elements can be used almost everywhere with little modification. For example, the head of the first brush may require that a limit force of 2.5 Newtons be exceeded before a signal is provided to the user that the brushing force applied is excessive. In contrast, the second brush head may require that a limit force of 3.5 Newtons be exceeded before a signal is provided to the user that the applied brushing force is excessive. Due to the modular nature of the insert elements 800, 900 and 1700, modification of the resilient element 890, 1790 and contact 965B, between the head of the first brush and the head of the second brush can provide the correct limit forces for the two brushes . Consequently, during the manufacture of the brushes, the insertion elements can be customized as necessary for a given brush head so that the proper limit force is provided by the insertion element.

[00097] To increase reliability during the manufacture of the brushes of the present invention, materials in the brush that may create a force contrary to the applied brushing force should be considered. For example, the first sealing element 70, the second sealing element 75 and / or the sealing element 1770 can offer some resistance to the movement of the loading element. Thus, in some embodiments, the material for the sealing elements is selected to be of Shore A hardness less than about 50. Similarly, the 1770 sealing element can have a reduced cross-sectional area adjacent to the 2730 indicating element thus decreasing the impact that the 1770 sealing element has on any force contrary to the applied brushing force.

[00098] It has been found that in relation to toothbrushes, consumers tend to disapprove of a substantial amount of movement in the toothbrush head area. Specifically, consumers tend to disapprove of excessive toothbrush head movement in a plane that is generally perpendicular to a 1010 pivot axis (shown in figure 10A). With reference to figures 10A to 10C, the movement of the head 1014 in this plane can be determined by measuring a distance in a straight line 1089 between a plane at rest 1061 and a plane of applied force 1063 where the straight line 1089 is orthogonal to the plane at rest 1061 and is tangent to the toothbrush head 1014 at an intersection 1071.

[00099] The resting plane 1061 extends through pivot axis 1010 and extends through the intersection 1071 between a side 1073 and a first face 1075 of the toothbrush head 14. In cases where the intersection 1071 includes a rounded edge, the point of intersection between side 1073 and the first surface 1075 will be the bisection of the rounded edge. Reference is made to the resting plane 1061 when there is no load on the field of contact elements 20.

[000100] The plane of applied force 1063, similarly to the plane at rest 1061, extends through the pivot axis 1010 and extends through the intersection 1071. Reference is made to the plane of applied force 1063 when there is a load predetermined 1090 applied to the cleaning element field 20. The predetermined applied load 1090 is 5 Newtons.

[000101] In some modalities, the distance in a straight line 1089 can be less than about 6 mm, less than about 5 mm, less than about 4 mm, less than about 3 mm, less than about 2 mm, less than about 1 mm and / or greater than about 1 mm, greater than about 2 mm, or any number within the described ranges, or any range including the described values.

[000102] Although, so far, the condition for which a signal is provided to the user is related to an excessively high applied brushing force, signals for other conditions or additional conditions can be provided to the user. For example, the user can be provided with a signal regarding the application of an excessively high brushing force being used; in addition, however, at least one of the following conditions can be similarly indicated to the user: (1) insufficient force is being applied; (2) sufficient force is being applied; (3) excessively high force is being applied, within a range just above sufficient force; (4) a much greater force is being applied (much greater than the proper force); (5) an upper limit has been reached for excessively high force being applied; (6) a lower limit has been reached for excessively low force being applied.

[000103] In some embodiments, signal combinations can be used for any combination of conditions. For example, to signal the user that insufficient force is being applied, a first signal can be audible while a second signal meaning excessive force can be used. visual. Any suitable combinations of signals can be used. As yet another example, to signal the user that insufficient force is being applied, a first signal can be visual and comprise a first color while a second signal meaning excessive force can, similarly , be visual, but that comprises a second color that contrasts with the first color. Any suitable colors can be used, for example, red, green, yellow, blue, purple, the like, or combinations thereof. Such signal combinations can also be applied in locations where the electromagnetic source is configured to provide a signal for sufficient strength and / or higher and lower values.

[000104] Several considerations can be taken into account in an attempt to assess the above conditions. For example, mouth feeling, cleaning efficiency, etc. With regard to mouth feeling, for example, mouth care implements that comprise cleaning elements that are very soft can, in general, provide a comfortable mouth feeling for a user under forces that are greater than that of mouth care implements that have elements harder cleaning agents. As another example, cleaning elements that comprise elastomeric materials may be more comfortable for a user and, therefore, may allow greater force to be applied during brushing and still remain within the user's comfort level. With respect to effectiveness, cleaning elements that have surface characteristics, as described in US Patent Nos. 5,722,106; 5,836,769; 6,058,541; 6,018,840; in US patent application publications No. 2006/0080794; 2006/0272112; and 2007/0251040; and PCT Publication No. WO2011 / 093874 may require less force during brushing to provide sufficient plaque cleaning / removal when compared to cleaning elements that have smooth surface characteristics.

[000105] Another consideration that can be taken into account includes clinical safety. For example, a force that provides a good mouth feel to the consumer can cause gum irritation, gum retraction and / or tooth enamel abrasion.

[000106] Several variables can affect the above considerations, for example, oral sensation, efficacy in cleaning, clinical safety. For example, users can apply a specific brushing force while using a toothbrush equipped with a motor and a different force while using a manual toothbrush. As another example, the length of the cleaning elements, the cross-sectional shape of the cleaning elements, for example, diameter, bending properties, etc. Due to the numerous variables that can affect the above considerations, consumer testing, clinical testing and / or robot testing can be used to empirically determine values for: (1) insufficient force being applied; (2) excessive force being applied; and / or (3) sufficient force being applied; (4) a lower limit of the sufficient force range being applied; and / or (5) an upper limit of the sufficient force range being applied, which can also provide comfortable oral sensation, cleaning efficiency and clinical safety.

[000107] Consumer tests and / or clinical tests can provide some insight into an adequate value for the upper tolerance limit of sufficient strength for a particular toothbrush and / or an appropriate value for the lower tolerance limit of sufficient strength for the particular toothbrush. In general, consumers can try a particular toothbrush and apply a recommended force while brushing. For example, the brushes of the present invention can be used to signal the user when the recommended force is reached, exceeded and / or not reached. After brushing, consumers may be asked to provide an opinion regarding the tactile sensation of the toothbrush in the oral cavity. Additionally, plaque scans of consumers' oral cavities can be obtained before brushing and then after brushing. The comparison can be made before and after to determine the effectiveness of a particular force. Above all, clinical tests can be performed at the upper limit of the force range sufficient to determine whether gum irritation, gum retraction and / or tooth enamel abrasion occurs at this strength value. Through iterative tests, appropriate limit force values during brushing can be determined for a variety of brush heads.

[000108] Similarly, tests with robots can be used to determine the effectiveness of a particular toothbrush at a given strength. In robot tests, in general, a toothbrush is operated by a robotic arm that moves the toothbrush in a brushing motion between the teeth of a model of an oral cavity. In general, the model's teeth are covered by a synthetic plate that is well known in the art. The robotic arm can apply a predetermined force to the toothbrush during the simulation. After the simulation, it is possible to compare the plate analysis before and after brushing. From the analysis of plaques before and after brushing, a determination of cleanliness / effectiveness can be made. Through iteration, the lowest level of the sufficient force range can be determined for any cleaning element / massage element configuration.

[000109] Each of these consumer tests, clinical tests and robot tests can provide useful information on force values associated with the following conditions: (1) insufficient force being applied; (2) excessive force being applied; and / or (3) sufficient force being applied; (4) a lower limit of the sufficient force range being applied; and / or (5) an upper limit of the sufficient force range being applied, which can also provide comfortable mouthfeel, as well as cleaning efficiency.

[000110] In some embodiments, an excessively high applied brushing force value may be greater than or equal to about 1 Newton, 1.25 Newton, 1.5 Newton, 1.75 Newton, 2.00 Newtons, 2, 10 Newtons, 2.20 Newtons, 2.30 Newtons, 2.40 Newtons, 2.50 Newtons, 2.60 Newtons, 2.75 Newtons, 2.85 Newtons, greater than or equal to about 3.00 Newtons, greater than or equal to about 3.50 Newtons, greater than or equal to about 3.75 Newtons, greater than or equal to about 4.00 Newtons, greater than or equal to about 4.25 Newtons, greater than or equal to about 4.50 Newtons, greater than or equal to about 4.75 Newtons, greater than or equal to about 5.00 Newtons, greater than or equal to about 5.25 Newtons, greater than or equal at about 5.50 Newtons, greater than or equal to about 5.75 Newtons, or greater than or equal to about 6.00 Newtons. In some embodiments, an insufficient force value being applied may be less than or equal to about 5.00 Newtons, about 4.75 Newtons, about 4.5 Newtons, about 4.25 Newtons, about 4, 00 Newtons, about 3.75 Newtons, about 3.5 Newtons, about 3.25 Newtons, about 3.00 Newtons, about 2.75 Newtons, about 2.50 Newtons, about 2.25 Newtons, about 2.00 Newtons, about 1.75 Newton, about 1.50 Newton, about 1.25 Newton, about 1.00 Newton, about 0.75 Newton, or about 0.50 Newton. In some embodiments, the values of a lower limit of a sufficient force range, an upper limit of a sufficient force range and / or the sufficient force range can be selected from any of the values provided above with respect to the conditions of use. excessive force and / or insufficient force.

[000111] The signal provided to the user can be constant, for example, a signal provided to the user in real time throughout the brushing routine. Alternatively, the signal provided to the user can be provided at the end of the brushing routine. For example, where the user applied an excessively high force during most of the brushing routine, the signal provided to the user can activate a first color or show the first color for a predetermined period of time. As another example, where the user applied an excessively low force during most of the brushing routine, the signal provided to the user can activate a second color or show a second color for a predetermined period of time. As yet another example, where the user applied sufficient force during most of the brushing routine, the signal provided to the user can activate a third color or show the third color for a predetermined period of time. As described so far, combinations of various signals can be used.

[000112] In other modalities, the signal can be supplied to the user intermittently during the brushing routine. For example, the signal can be provided to the user at predetermined time intervals. For example, a signal can be provided to the user every 20 seconds. Any suitable time interval can be selected. For example, the time interval between signals can be greater than about 0.1 second, greater than about 0.2 second, greater than about 0.3 second, greater than about 0.4 second, greater than about 0.5 seconds, greater than about 0.6 seconds, greater than about 0.7 seconds, greater than about 0.8 seconds, greater than about 0.9 seconds, greater than about 1 second, greater than about 2 seconds, greater than about 3 seconds, greater than about 4 seconds, greater than about 5 seconds, greater than about 6 seconds, greater than about 10 seconds, greater than about 15 seconds, greater than about 20 seconds, greater than about 25 seconds, greater than 30 seconds, greater than 40 seconds, greater than 50 seconds, greater than about 60 seconds, and / or less than about 60 seconds, less than about 50 seconds, less than about 40 seconds, less than about 30 seconds, less than about 25 seconds, less than about 20 seconds , less than about 15 seconds, less than about 10 seconds, m less than about 5 seconds, less than about 4 seconds, less than about 3 seconds, less than about 2 seconds, less than about 1.5 seconds, less than about 1 second, less than about 0.9 seconds, less than about 0.8 seconds, less than about 0.7 seconds, less than about 0.6 seconds, less than about 0.5 seconds, less than about 0.4 seconds, less than about 0.2 seconds, or less than about 0, 1 second, or any number within the described ranges, or any range including the described values.

[000113] The toothbrushes of the present invention may further comprise a processor. The processor may be in communication via signal with the load element and the electromagnetic source. The processor can be used to record user performance during brushing. For example, the user can brush for a predetermined period of time, for example, two minutes, after which the processor can cause the electromagnetic source to provide the user with a signal indicating that sufficient force has been applied. during the two minute period. As another example, the processor can cause the electromagnetic source to provide the user with a signal that sufficient force has been applied for about half the two-minute period. As yet another example, the processor can cause the electromagnetic source to provide the user with a signal that excessively high force has been applied throughout and / or more than fifty percent of the two-minute period. As yet another example, the processor can cause the electromagnetic source to provide the user with a signal that an excessively low force has been applied throughout and / or more than fifty percent of the two minute period. The signals provided to the user may include the signals described previously.

[000114] Additionally, the processor can be useful to eliminate power peaks from the indication. In such embodiments, the processor can serve as a buffer for the electromagnetic source creating a delay between the occurrence of the condition and the signal provided by the electromagnetic source. For example, the processor can be configured to include a five-second delay so that an excessively high applied brushing force must remain excessively high for at least five seconds before the processor causes the electromagnetic source to provide a signal to the user . Configured in this way, the processor can filter the input of the load element so that the electromagnetic source does not cause a plurality of flashing signals to the user. The delay can be any suitable delay. For example, in some modes, the delay may be less than about 10 seconds, less than about 9 seconds, less than about 8 seconds, less than about 6 seconds, less than about 5 seconds, less than about 4 seconds, less than about 3 seconds, less than about 2 seconds, less than about 1 second apart, less than about 1 second , 75 seconds, less than about 0.5 seconds, less than about 0.25 seconds, less than about 0.10 seconds.

[000115] Other suitable mechanisms can be used to reduce and / or eliminate power peaks. For example, in some modalities a low pass filter of at least the first order can be used. In such embodiments, the low-pass filter can prevent a power surge from causing the electromagnetic source to provide an output due to the high frequency of the power surge. As another example, the processor can be programmed to include a digital filter that can eliminate power surges, preventing them from causing the electromagnetic source to provide an output. Peak power filtration is described in US Patent No. 7,120,960.

[000116] A time interval between signals was previously discussed. In some embodiments, the processor can be configured to modify the time interval between the signals provided to the user during a particular brushing routine or over a series of brushing routines. For example, during a first brushing routine, if the user alternates between excessive force and / or insufficient force, the interval between signals to the user may occur in a first interval of time. However, if in the first brushing routine the user also applies a force that is predetermined to be within the sufficient strength range, the signals to the user may occur in a second interval of time. In such a modality, the first time interval can be smaller than the second time interval, thus providing one more opinion for the user. In some embodiments, the time intervals can be alternated so that the user receives one more opinion for forces that fall within a predetermined range of sufficient strength.

[000117] As previously stated, the processor can similarly modify the time interval between the signals provided to the user over a series of brushing routines. For example, during a first brushing routine, the user may apply excessive force and / or insufficient force during most of the time of the first brushing routine. During the first brushing routine, the time interval between signals may occur in a first time interval. The processor can be configured to process data relating to the force applied during the first brushing routine and to modify the time interval for the next brushing routine. For example, for a second brushing routine, based on the data from the first brushing routine, the processor can modify the time interval between signals during the second brushing routine for a second time interval. The second time interval can be smaller than the first time interval so that the user can receive one more opinion during the second brushing routine. If, during the second brushing routine, the user, during most of the time of the second brushing routine, applies a force within a sufficient force range, then the processor can modify the time interval between signals for a third brushing routine. For example, the time interval between signals for the third brushing routine may be less than the second time interval. However, if during the second time interval the user applies, during most of the second brushing routine, a very strong and / or very weak force during most of the time period of the second brushing routine, then the processor can adjust the time interval between signals for the third brushing routine to a value less than the second time interval so that the user receives even more of an opinion than in the second brushing routine. In some embodiments, the processor may be configured to provide an additional opinion regarding a force within the sufficient force range at increasing and / or decreasing time intervals.

[000118] The electromagnetic source can comprise a plurality of visual components, for example, LEDs. The use of at least one light source and / or a plurality of light sources to provide an opinion to the user is discussed in more detail in US Patent No. 7,120,960 and PCT application serial number IB2010 / 051194 , entitled "Electric Toothbrush and Method of Manufacturing an Electric Toothbrush", filed on March 18, 2010. As previously discussed, the toothbrushes of the present invention can comprise a processor. In such embodiments, the processor may be in electrical communication with the electromagnetic output source so that the processor can control the output of the electromagnetic output source.

[000119] In some embodiments, a receptacle (discussed so far) of a load element can be configured so that two LEDs can be positioned on it. A first LED can provide a first output signal for a condition, for example, brushing time, while a second LED can provide a second output signal for a second condition, for example, brush replacement time, the first being output signal and the second output signal are different. Similarly, in embodiments where the transmission element does not include a receptacle, a plurality of output sources, for example, LEDs, can be used.

[000120] Instead of a plurality of LEDs, modalities are also contemplated in which the output source comprises an LED that has multiple cubes as described in US patent application publication No. 2005 / 0053896A1. As shown in Figure 11A, an LED 1115 can include a lens 1130, and a positive lead 1121 and a negative lead 1109. LED 1115 can comprise more than one light emitter and more than one semiconductor substrate, and can have more two-wire. Modes are contemplated in which the LED comprises two cubes. Additionally, modalities are contemplated in which the LED comprises more than two cubes.

[000121] For example, LED 1115 can comprise multiple light-emitting hubs 1105 and 1117 and a wired connection 1107 and 1118. Wired connection 1118 can serve as the connection between hubs 1105 and 1117. This connection can be a parallel connection or a serial connection.

[000122] As shown in figure 11B, an LED 1115B (two-wire LED) can comprise multiple hubs 1105 and 1117 connected in series. LED 1115B can include a positive lead 1109 and a negative lead 1127. As shown, each hub 1105 and 1117 can have an individual pedestal 1137 and 1139. The hubs have a serial connection 1111 connecting the top of hubs 1105 to the base of the hubs. hubs 1117, and wire link 1113 connects the top of hubs 1117 to the negative lead wire 1127. All light from light emitting sources can be combined to result in a single light output on the 1130 lens of LED 1115B.

[000123] As shown in figure 11C, an LED 1115C can include multiple hubs 1105 and 1117 connected in parallel. The LED 1115C can comprise a single light outlet, the lens 1130, a positive lead 1109, and a negative lead 1127. The hubs can have a parallel connection, a wire connection 1137 connecting the top of the hubs 1105 to the top of the hubs. cubes 1117, and a wire connection 1107 connecting the top of cubes 1117 to the top of the common negative lead wire 1127. All light from the light emitting sources can be combined to result in a single light output on the 1130 lens of the LED 815C .

[000124] As shown in figure 11D, an LED 1115D (three-wire LED) can include multiple cubes 1105 and 1117. LED 1115D can comprise a 1130 lens, two semiconductor substrates, cubes 1105 and 1117 shown connected in parallel, the wire connections 1119 and 1121, one positive conductive wire 1133 and two negative conducting wires 1131 and 1135. This LED 1115D also emits light from a single light outlet, the 1130 lens. Each cube can have an individual pedestal 1137 and 1139 In the present description it is also contemplated that LED 1115D can comprise two positive conductors and one negative conductor; and that hubs 1105 and 1117 can be connected in series.

[000125] Additionally, the LED can comprise more than two semiconductor substrates having light emitting properties, and the LED can comprise more than two conductors. The LED can have a common, or shared, conductor, or it can have individual conductors for each semiconductor substrate having light emitting properties. In addition, each semiconductor substrate having light emitting properties can be individually powered by a separate energy source, such as a battery.

[000126] An advantage of a three-wire LED, for example, LED 1115D, is that hubs 1105 and 1117 can be operated independently. For example, in modes where LED 1115D comprises two positive conductors, the hubs can be controlled independently. In this way, the first hub 1105 can be operated at eighty percent capacity, while the second hub 1107 is operated at twenty percent capacity. As another example, the first hub 1105 can be operated at fifty percent, while the second hub 1117 is operated at 100 percent. There are countless combinations of operating levels of the first cube 1105 and the second cube 1117. It is believed that such combinations can create mixtures of colors resulting in a unique visual effect for the user.

[000127] For two-wire LEDs, color mixes are also possible. For example, the polarity of the supply voltage can be changed at a sufficiently high rate, for example, greater than 70 Hz, so that the cubes can be driven and create a mixed color effect. When the polarity of the supply voltage is in a first state, a first cube can be energized. When the polarity of the supply voltage is in a second state, a second cube can be energized. If the polarity of the supply voltage power is changed fast enough, a user may notice a mixture of colors. The rate of change of the supply voltage polarity can be greater than about 70 Hz, greater than about 80 Hz, greater than about 90 Hz, greater than about 100 Hz, greater than about 110 Hz, greater than about 120 Hz, greater than about 130 Hz, less than about 130 Hz, less than about 120 Hz, less than about 110 Hz, less than about 100 Hz, less than about 90 Hz, or any number within of the described ranges, or any range including the described values.

onde n é igual ao número de cubos e Vf = voltagem direta para um cubo particular. Se os cubos forem conectados em paralelo, a voltagem total será aproximadamente a voltagem de um único cubo.[000128] As stated earlier, these hubs can be connected electrically in parallel or in series. When connected in series, all current considerations are the same as for a single hub. The total voltage can be approximated by the equation below:

where n is equal to the number of cubes and Vf = direct voltage for a particular cube. If the hubs are connected in parallel, the total voltage will be approximately the voltage of a single cube.

[000129] The serial connection works well because it adjusts to differences between the cubes. When connected in series, the cubes automatically adjust their direct voltages and their luminous intensities become very close. In either arrangement, the two cubes have approximately 1.6 x Pi light intensity, where Pi is the light intensity of a single cube. A three-cube LED will probably have a light intensity of around 2.26 x Pi. (Interference between cubes can prevent the calculation of light intensity from multiplying by the number of cubes.) These cubes can produce the same color of light, or they can have different colors of light. However, if each individual light emitter emits the same light, the luminous intensity of that color from that single LED will be greater than that of a single standard LED emitting light of one color.

[000130] A single LED could also contain two cubes emitting different colors of light, such as, for example, a wavelength selected from the range between greater than about 370, 380, 390, 400, 425, 440, 450, 475 or 480, and / or less than about 500 nanometers. The cubes could also be selected in order to emit light of a different wavelength within the same range of colors; for example, the cubes could emit light with different wavelengths resulting in the color blue. Some colors are difficult to obtain by a single wavelength of light; this invention can be used to produce light in one of these unique colors. Therefore, the combination of different colors in the single optical output can result in a color that cannot be obtained through a single cube.

[000131] For modalities comprising multiple LEDs or one LED with multiple cubes, the oral hygiene implement of the present invention can provide the user with multiple signals. For example, a first cube can be energized and provide the user with a first visual signal. The first visual signal can be correlated to a predetermined brushing time interval performed by the user, for example. A second cube can be energized by providing the user with a second visual signal. The second visual signal can indicate to the user that it is time to replace the device for oral treatment. In such embodiments, the first visual indication may comprise a first color, while the second visual indication comprises a second color that is different from the first color. Any suitable colors can be used.

[000132] For output signals that comprise a visible signal, the replacement of a light source, for example, can be in any suitable location. Although the light source can be arranged on the cable, there is a tendency for the light source to be hidden from the user's view by the user's own hand. To facilitate user viewing, an area overlapping the neck and cable can be particularly beneficial as the location of the light source. The area can be arranged on a posterior surface of the toothbrush.

[000133] Additionally, the light source can be selected so that it has a wide dispersion angle. The light source can be positioned on the toothbrush so that the light from the light source is in the user's line of sight. In some embodiments, the light source can be positioned so that the light emitted by the light source shines on the user's face. For example, light from the light source can illuminate the user's face when activated. The brightness of the light on the user's face can facilitate viewing by the user even in the absence of a mirror. In such embodiments, the light source can be positioned asymmetrically with respect to a longitudinal axis of the toothbrush. In such modalities, the light source can be positioned at an angle towards the user's face.

[000134] The toothbrush of the present invention may additionally comprise a timer. The timer can be positioned inside the toothbrush or it can be arranged on a remote display. The timer can be configured to start automatically as a brushing force is applied. Regardless, or in conjunction with the application of the brushing force, the timer can be activated by the movement of the toothbrush. In such embodiments, the toothbrush may comprise accelerometers or another device suitable for measuring / monitoring the movement of the toothbrush. Such devices for monitoring / measuring toothbrush movement are described in US patent application serial number 61 / 116,327, entitled, "PERSONAL CARE SYSTEMS, PRODUCTS, AND METHODS", filed on November 20, 2008. An example A suitable timer is a 555 timer integrated circuit available at many electronics stores where integrated circuits are sold.

[000135] The toothbrush of the present invention may further comprise an energy source as discussed above. The power source can be any suitable element that can supply power to the toothbrush. A suitable example includes batteries. The battery can be sized to minimize the amount of real states needed inside the toothbrush. For example, when the electromagnetic source consists of a light-emitting element or vibrating motor (used to signal to the user and not to vibrate the head cleaning elements and / or head movement), the energy source can be relatively large small, for example, smaller than a AAA battery. In such embodiments, the vibrating device can be relatively small. The battery can be rechargeable or it can be disposable. In addition, a plurality of batteries can be used. In some embodiments, the power source may include alternating current supply as provided by a utility company to a home. Other suitable energy sources are described in US patent application serial number 12/102881, filed on April 15, 2008, and entitled, "Personal Care Products and Methods".

[000136] In some modalities, a user-operated switch can be provided that allows the user to control when the pressure indication should start, as well as when the timer should start. The switch may be in electrical communication with the power source and the electromagnetic source and / or the timer.

[000137] In some embodiments, the toothbrush of the present invention may comprise a system for oral treatment that additionally comprises an external display that is communicating via signal with the toothbrush. In such modalities, communication between the external display and the toothbrush can be done in any suitable way. Some suitable examples of communication between a personal hygiene device, for example, a toothbrush, and an external display are described in US patent applications serial number 61 / 176,618, entitled, "PERSONAL CARE SYSTEMS, PRODUCTS, AND METHODS" , filed on May 8, 2009; 61 / 180,617, entitled, "PERSONAL CARE SYSTEMS, PRODUCTS, AND METHODS", filed on May 22, 2009; and in US patent application publication No. 2008/0109973. In such embodiments, the signal discussed in the present invention can be provided to the user through the external display and / or by means of the indicating element.

[000138] Any suitable material can be used for the first and second sealing elements. Some examples of suitable materials include thermoplastic elastomers, silicone, nitrile butadiene rubber, ethylene propylene diene monomer rubber, or the like. Other suitable examples include thermoplastic elastomers, silicone-based materials, NBR (nitrile butadiene rubber), EPDM (ethylene propylene diene monomer rubber), Viton ™, etc. In addition, the sealing elements can be attached to the cable in any suitable manner, for example, by overlapping molding. In some embodiments, the cable and sealing elements can overlap to some extent to help reduce the likelihood of contaminants entering the junction between the sealing elements and the cable. In some embodiments, the material of the sealing elements may also extend over a portion or portions of the cable, to provide a gripping surface, for example, elastomeric gripping features.

[000139] In some embodiments, the sealing elements and / or the elastomeric gripping feature (s) may include visual texture or features that provide a visual signal indicating the flexibility of the toothbrush. For example, as shown in figure 12, a toothbrush 1410 can comprise a handle 1412 that has a first sealing element 1270 and a second sealing element 1275. The first sealing element 1270 and / or the second sealing element 1275 can comprise roughnesses 1480 1480 roughness can provide the consumer with visual communication regarding the flexibility of the toothbrush. As shown, an indicating element 1230 can be positioned between the first sealing element 1270 and the second sealing element 1275 which can allow the indicating element 1230 to provide a visual signal to the consumer.

[000140] As stated previously, the first sealing element and / or second sealing element, as described here, can be transparent and / or translucent. In such embodiments, the sealing elements can accentuate a visual signal showing the light distributed by the reflective core.

[000141] The cable can be of any suitable material. Some examples of suitable materials include polypropylene, ABS (acrylonitrile-butadiene-styrene copolymer), ASA (styrene acrylonitrile acrylate), copolyester, POM (polyformaldehyde), combinations thereof, and the like. Other suitable materials include polypropylene, nylon, high density polyethylene, other stable, similar moldable polymers, and / or combinations thereof. In some embodiments, the cable, the neck and / or the head can be formed from a first material and include recesses, channels, grooves, to receive a second material that is different from the first. For example, the cable may include an elastomeric gripping feature or a plurality of elastomeric gripping features. Elastomers among the plurality of elastomeric gripping features may be similar materials or may be different materials, for example, in color, hardness, combinations of these or similar characteristics.

[000142] The elastomeric resources of gripping the cable can be used to overmould, at least in part, a portion of the timer, electromagnetic source, processor, indication element and / or power source. In such modalities, these components can be in electrical communication by means of wiring that can similarly be overmoulded. Elastomeric gripping features may include portions that are positioned for grip by the user's palm and / or portions that are positioned for grip by the user's thumb and index finger. These elastomeric gripping features can be composed of the same material or can be different, for example, in color, shape, composition, hardness, similar, and / or combinations thereof.

[000143] The elastomeric resources of gripping the cable can be in communication with a channel, groove and / or recess, in the neck through a channel, groove, external recess and / or through a channel, groove, internal recess. In some modalities, the elastomeric gripping features may be in communication with a channel, groove and / or recess in the head through a channel, groove and / or internal recess, and / or a channel, groove and / or external recess. Alternatively, the cable grip features may be distinct elements from the head and / or neck features.

[000144] In some modalities, recycled plastics and / or of vegetable origin can be used. For example, in some modalities PET can be used. PET can be bio based. For example, PET can comprise from about 25 to about 75%, by weight, of a terephthalate component, and from about 20 to about 50%, by weight, of a diol component, with at least about one percent by weight of at least one of a terephthalate and / or diol component is derived from at least one bio based material. Similarly, the terephthalate component can be derived from a bio based material. Some examples of bio based materials include but are not limited to corn, sugar cane, sugar beet, potato, starch, citrus, woody plant, cellulosic lignin, plant oil, natural fiber, oily wood raw material, and a combination of the same.

[000145] Some of the specific components of PET can be bio based. For example, monoethylene glycol and terephthalic acid can be formed from bio based materials. The formation of bio-based PET and its manufacture are described in US patent application publication No. 20090246430A1 and 20100028512A1.

[000146] Additionally, for use in the present invention, the term "contact elements" is used to refer to any suitable element that can be inserted into the oral cavity. Some suitable elements include tufts of bristles, elastomeric massage elements, elastomeric cleaning elements, massage elements, tongue cleaners, soft tissue cleaners, hard surface cleaners, combinations thereof, and the like. The head can comprise a variety of contact elements. For example, the head may comprise bristles, abrasive elastomeric elements, elastomeric elements in a particular orientation or arrangement, for example, hinge fins, prophylactic cups, or the like. Some suitable examples of elastomeric cleaning elements and / or massage elements are described in US patent application publications No. 2007/0251040; 2004/0154112; 2006/0272112; and in US Patent Nos. 6,553,604; 6,151,745.The cleaning elements can be tapered, notched, crimped, corrugated, or similar. Some suitable examples of such cleaning elements and / or massage elements are described in US Patent Nos. 6,151,745; 6,058,541; 5,268,005; 5,313,909; 4,802,255; 6,018,840; 5,836,769; 5,722,106; 6,475,553; and in US patent application publication No. 2006/0080794.

[000147] The contact elements can be fixed to the head in any suitable way. Conventional methods include stapling, tufting free of anchors, and tufting with injection mold. For contact elements comprising an elastomer, these elements can be formed integrally with each other, for example, having an integral base portion and extending out of it.

[000148] The head may comprise a soft tissue cleaner constructed from any suitable material. Some examples of suitable materials include elastomeric materials; polypropylene, polyethylene, etc .; similar, and / or combinations thereof. The soft tissue cleaner can comprise any suitable soft tissue cleaning elements. Some examples of such elements, as well as soft tissue cleaner configurations on a toothbrush are described in US patent applications No. 2006/0010628; 2005/0166344; 2005/0210612; 2006/0195995; 2008/0189888; 2006/0052806; 2004/0255416; 2005/0000049; 2005/0038461; 2004/0134007; 2006/0026784; 20070049956; 2008/0244849; 2005/0000043; 2007/140959; and in US Patent Nos. 5,980,542; 6,402,768; and 6,102,923.

[000149] For the modalities that include an elastomeric element on a first side of the head and an elastomeric element on a second side of the head (opposite to the first), the elastomeric elements can be formed integrally through channels or gaps that extend through of the head material. These channels or openings can allow the elastomeric material to flow through the head during an injection molding process so that the elastomeric elements on the first and second sides can be formed in an injection molding step.

[000150] In modalities that include a soft tissue cleaner, consumer testing, robot testing and / or clinical testing can be performed so that an upper strength limit and a lower strength limit can be established to provide an opinion for the user regarding the force applied to a soft tissue, for example, tongue. For modalities that include a soft tissue cleaner, the toothbrush may comprise an accelerometer or other suitable device for monitoring the orientation of the toothbrush. In combination with the applied force, for example, brushing force, the processor can determine whether the soft tissue cleaner is being attached or whether the cleaning elements are being attached. The signal or a plurality of signals can be provided to the user as described here. Providing an opinion to the user regarding the force applied to the soft tissue can help the user to avoid soft tissue injuries, for example, papillae, and still achieve an effective cleaning.

Test method to determine the applied force for which an indication occurs

[000151] The test to determine an applied force for which an indication occurs requires an adjustable frame and a 1697 force indicator (shown in figure 16). The force indicator used must be capable of providing force readings with at least two places to the right of one tenth (hundredths of a Newton). A suitable strength indicator is available from Lutron Electronic Enterprise Co., Ltd., and available under model number FG-20KG. Before testing, the strength indicator must be calibrated according to the manufacturer's recommendations, or must be sent to the manufacturer for calibration.

[000152] As shown in figure 13, place a sample of the 1300 toothbrush in a 1050 three-point attachment over the adjustable frame. The three-point attachment 1350 will support a toothbrush handle region 1312 through a first point 1302, a second point 1304 and a third point 1306. Points 1302, 1304 and 1306 must be adjusted to eliminate movement of the region of cable 1312 during testing. In addition, the toothbrush 1300 must be attached to the accessory 1350, so that the head 1314 (shown in figure 14) is substantially parallel to a horizontal surface.

[000153] A pull block 1320 is attached to the head 1314 (shown in figure 14 and covered by the pull block 1320 in figure 13) of the toothbrush 1300. The pull block 1320 must be produced from a rigid material that allow a force of 10 Newtons to 15 Newtons to be applied to the toothbrush head 1314 1300. As shown in figure 14, the pull block 1340 must engage a top surface 1475 of the head. No cleaning elements 1421 should be positioned between the top surface 1475 and the pulling block 1420. If necessary, the cleaning elements 1421, or a portion thereof, can be removed to allow the pulling block 1420 to engage properly with the top surface 1475 of head 1314.

[000154] The pull block 1420 must be constructed so that a hook 1440 can extend from a bottom side 1490 of the pull block 1420. The hook 1440 can be attached in any suitable way to the pull block 1420. The hook 1440 must be rigidly attached to the pulling block 1420, so that the hook 1440 does not move in relation to the pulling block 1420 during testing. The hook 1440 must be positioned on the pull block 1420 so that a center line 1441 of the hook 1440 bisects a distance 1460 from the cleaning elements 1421. The distance 1460 is the maximum straight line distance between the cleaning elements further apart from each other along a lateral direction.

[000155] As shown in figure 15, the hook 1440 must be positioned on the pulling block 1420 so that the center line 1441 bisects a distance 1470 from the cleaning elements 1421. The distance 1470 is the maximum straight line distance between the elements cleaning devices that are further away from each other along a longitudinal direction.

[000156] Hold the power indicator 1697 from the hook 1440 of the pull block 1420. A lower limit (not shown) of the power indicator 1697 must be attached to the horizontal surface to which the head 1314 (shown in figure 13) of toothbrush is substantially parallel. The 1697 power indicator is attached to the horizontal surface so that the power indicator is perpendicular to the horizontal surface. Lift the adjustable frame until an indication of a predetermined force is provided by the 1300 toothbrush. Record the reading on the 1397 strength indicator. Repeat the test five times with additional samples from the 1300 toothbrush.

Test method to determine the efficiency of light emission

[000157] Obtain three samples of the brush to be tested and three samples of the output source used in the brush. The samples from the output source must be identical to those used in the brush. Take all samples, that is, three brush samples and three samples from the output source, to an independent testing laboratory. The test lab will test each of the three brush samples and each of the output source samples on an appropriately sized integrating sphere. For example, a 30.5 cm (12 inch) integrating sphere may be suitable for fitting brush samples.

[000158] The testing laboratory will calibrate all equipment before starting the measurement of any samples. The samples from the output source will be tested before brush testing. The test lab will place a sample of the output source in the integrating sphere according to standard test procedures. The output source will be powered by the same voltage as that supplied on the brush. Specifically, if the brush uses two 1.5 volt clock batteries, then the output source will also be powered by two 1.5 volt clock batteries.

[000159] The output source will be activated, the integrating sphere closed and the total amount of light emitted by the output source will be measured. All other output source samples will be measured in a similar way. The total light output of each sample of the output source will be recorded and noted for each sample.

[000160] Remove the source sample from the integrating sphere before testing a sample brush. Place a sample brush on the integrating sphere configured to activate the brush output source without blocking the light emitted from the brush indicating element. For example, in cases where the indicating element provides a visual indication of excessive pressure being applied, an electrical harness can be used to move the brush head / neck assembly to ensure that the indicating element / output source is activated. Measure the total amount of light emitted from the sample brush. Repeat the procedure for the remaining brush samples.

[000161] The total amount of light emitted from the sample output source 1 will be divided by the total amount of light emitted by the sample brush 1. The quotient is then multiplied by 100 to determine the percentage of the sample 1. The total amount of light emitted by the sample output source 2 will be divided by the total amount of light emitted by the sample brush 2. The quotient is then multiplied by 100 to determine the percentage of the sample 2. The total amount of light emitted by the sample output source 2 sample 3 will be divided by the total amount of light emitted by the sample brush 3. The quotient is then multiplied by 100 to determine the percentage of sample 3. Percentages 1, 2 and 3 will be averaged to obtain the percentage efficiency.

[000162] The dimensions and values presented in the present invention should not be understood as being strictly limited to the exact numerical values mentioned. Instead, unless otherwise specified, each of these dimensions is intended to mean both the mentioned value and a range of functionally equivalent values around that value. For example, a dimension displayed as "40 mm" is intended to mean "about 40 mm".

Claims (12)

1.Cable (12) for oral hygiene that has a compartment, a cavity in it and an insertion element (200) disposed inside the cavity, characterized by the fact that the insertion element (200) comprises: a loading element (230) capable of rotating in relation to the compartment; an output source (250) arranged in electromagnetic communication with the load element (230), the output source (250) having a first contact arm (265A) and a second contact arm (265B); a power source (240) in electrical communication with the output source (250), the power source (240) having a first contact area and a second contact area; a coupling section (316) capable of receiving an accessory for oral treatment; and an indicating element (30) forming a surface facing away from the cable (12), where when the load element (230) rotates a predetermined amount, the first contact arm (265A) makes contact with a first area of contact. contact and / or the second contact arm (265B) makes contact with the second contact area thus causing the power source (240) to supply power to the output source (250), where an output source (250 ) supplies electromagnetic energy to the charging element (230), the charging element (230) transmitting the electromagnetic energy from the output source (250) to the indicating element (30), and the charging element ( 230), the indicating element (30) and the engagement section (316) are integral with each other. 2. Cable (12) for oral hygiene, according to claim 1, characterized by the fact that it additionally comprises a reflective core (661) disposed between the load element (230) and the indicating element (30 ), the reflective core (661) distributing electromagnetic energy from the charging element (230) to the indicating element (30). 3. Cable (12) for oral hygiene, according to claim 1, characterized by the fact that the reflective core (661) comprises a polished area arranged inside the indicating element (30). 4. Cable (12) for oral hygiene, according to claim 1, characterized by the fact that the charging element (230) transmits the electromagnetic energy of the output source (250) by means of internal reflection. 5. Cable (12) for oral hygiene, according to claim 1, characterized by the fact that the load element (230) comprises a receptacle (553A, 553B, 553C, 553D) for the output source (250 ). 6. Cable (12) for oral hygiene, according to claim 1, characterized by the fact that the load element (230) comprises a material that has a refractive index greater than about 1.0. 7.Cable (12) for oral hygiene, according to claim 6, characterized by the fact that the refractive index is greater than about 1.5. 8.Cable (12) for oral hygiene, according to claim 1, characterized by the fact that it additionally comprises a support (815), the support (815) being fixedly connected to the cable, so that during operation the support (815) does not move in relation to the cable. 9.Cable (12) for oral hygiene, according to claim 8, characterized by the fact that the load element (230) is hingedly attached to the support (815). 10.Cable (12) for oral hygiene, according to claim 8, characterized by the fact that the load element (230) is integral with the support (815). 11.Cable (12) for oral hygiene, according to claim 1, characterized by the fact that it additionally comprises a first sealing element and a second sealing element, the first sealing element being located between the cable (12) and the insertion element (200), and the second sealing element is positioned between the indicating element (30) and the engagement section (316). 12.Cable (12) for oral hygiene, according to claim 11, characterized by the fact that the first sealing element and / or the second sealing element are translucent or transparent.

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