CN111345521A - Intelligent bra - Google Patents

Abstract

An intelligent bra, comprising: brassiere body and gas collection actuator, the brassiere body contains: the cup structure comprises an outer surface layer, an inner surface layer and an air bag layer, wherein the air bag layer is coated between the outer surface layer and the inner surface layer, comprises an air channel and is provided with a connecting end extending out of the cup structure; the gas collection actuator is connected to the connecting end and comprises a gas conveyor, a control module and a gas pressure detector, the gas conveyor is used for supplying and conveying gas to the air bag layer to adjust the internal pressure, the control module is used for controlling the operation of the gas conveyor and controlling the set threshold value mode of the gas pressure detector, and the gas pressure detector is used for detecting the required gas pressure in the air bag layer so as to monitor and inform the control module to control the operation of the gas conveyor.

Description

Intelligent bra

Technical Field

The present invention relates to a brassiere, in particular, it relates to an inflatable and intelligent brassiere capable of making breast cancer detection.

Background

For modern women, bras have been an indispensable product. The stability of the bra when wearing is a ring of great importance for women, if the stability of the bra is not good, the bra is easy to slip and dislocate along with the limb movement of the wearer, the wearer can feel no safety and feel uncomfortable, and the wearer needs to readjust the position of the bra frequently, thereby causing inconvenience to the wearer.

In addition, most modern women wear the bra for a long time, so the comfort of wearing the bra is also the key point of the women when choosing the bra. In addition, when wearing the bra, the breasts can be intensively supported to make the bra beautiful, and the bra also helps to prevent the breasts from expanding outwards and sagging, so modern women also pay considerable attention to the centralized supporting effect of the bra.

In the known bra, hard steel rings are used to support the cups, and a steel ring is sewn on the lower edge of each of the two cups of the bra, so that the steel ring made of metal provides sufficient strength and supporting force to stably support the breast shape and to support and concentrate the breast.

However, the steel ring has good rigidity but insufficient elasticity, and is easy to deform, and the steel ring is close to the breast of the female, so that the female feels a foreign body feeling and a foreign body pressing feeling, and the user feels uncomfortable and has a pressing feeling after wearing the steel ring for a long time.

In view of the above, many bra without steel ring have been designed in the workshop, however, although the bra without steel ring meets the requirement that the general women want no steel ring in the bra, the bra without steel ring has no support and height support of steel ring, so the effect of concentrating the breast is reduced, therefore the bra without steel ring can deform the female breast shape and is not beautiful, which is also an important problem to the women.

In addition, nowadays, women suffering from breast cancer have an increasing rate year by year, so a touch detector has been developed in the market, which can sense the change of the surface of the breast, and transmit the detected data to a detection receiving device (such as an application software of a smart phone or a computer) for data analysis, and then transmit the data to an intelligent medical detector, so as to track the change of the breast and form a notification report. However, the requirement of the tactile detector for detection is that the tactile detector needs to be tightly attached to the breast for detection, and if the tactile detector is generally directly attached to the breast, the detection precision of the tactile detector is affected due to the fact that the surface of the breast is a curved surface and has variable factors such as difficulty in attachment and incapability of completely attaching.

Therefore, how to develop a bra, which can maintain the supporting capability of the bra to the breast when no steel ring is used, and can maintain the concentrated supporting effect of the bra using the steel ring and the effective and accurate breast detection benefit, is the problem to be solved in the field.

Disclosure of Invention

The present invention provides an intelligent bra, which solves the problems of insufficient supporting force of the bra on the breast and the fitting property of the bra during the breast detection in the prior art, therefore, the intelligent bra uses a gas collection actuator to match with an air bag layer arranged in a cup structure, the air bag layer in the cup structure is inflated or deflated by a gas conveyor of the gas collection actuator, and the air pressure detector of the gas collection actuator is matched with a set threshold value mode to monitor and adjust the proper inflation quantity of the air bag layer in the cup structure, so as to adjust the air pressure in the air bag layer, and the pressure change therein can be used to change the shape, hardness, supporting strength and other properties of a first cup and a second cup on the cup structure, thereby users can adjust the intelligent bra according to their own requirements, so as to achieve the effects of stable support and lifting, and the touch detector of the breast is arranged and fitted on the cup structure, the air bag layer is used for pushing the touch detector to be adjusted according to the shape of the breast so as to be more attached to the surface of the breast for detection, so that the detection accuracy of the touch detector is improved, and the intelligent bra can meet different requirements of each user.

To achieve the above object, the present invention provides an intelligent bra, comprising: a bra body, comprising a supporting structure, a cup structure and two groups of fixing structures, wherein the supporting structure is used for bearing the cup structure and is connected with the two groups of fixing structures, each fixing structure is respectively and correspondingly arranged on one side of the supporting structure and is used for being buckled with each other, the cup structure comprises an outer surface layer, an inner surface layer and an air bag layer, the air bag layer is coated between the outer surface layer and the inner surface layer, the air bag layer comprises an air channel and is provided with a connecting end which extends out of the cup structure; and a gas collection actuator, which is connected to the connecting end of the gas channel and comprises a gas conveyer, a control module and a gas pressure detector, wherein the gas conveyer is used for supplying gas to the air bag layer in the cup structure to adjust the internal pressure, the control module is used for controlling the operation of the gas conveyer and controlling the set threshold value mode of the gas pressure detector, and the gas pressure detector is used for detecting the required pressure of the gas in the air bag layer to monitor and inform the control module to control the operation of the gas conveyer.

Drawings

Fig. 1 is a schematic front view of an intelligent bra according to a preferred embodiment of the present disclosure.

Fig. 2 is a sectional view of the intelligent bra of the preferred embodiment shown in fig. 1 along the section line a-a' for inflating.

Fig. 3 is a schematic cross-sectional view illustrating the structure of the intelligent bra according to another preferred embodiment of the present disclosure.

Fig. 4A is a schematic cross-sectional view of the gas conveyer of the present invention.

Fig. 4B to 4C are schematic views illustrating the operation of the gas conveyer in fig. 4A.

FIG. 4D is a schematic diagram illustrating the pressure relief operation of the gas delivery device of FIG. 4A.

Fig. 5A is an exploded view of the micro pump of the present invention.

Fig. 5B is an exploded view of the micro-pump from another perspective.

Fig. 6A is a schematic cross-sectional view of the micro pump of the present invention.

FIG. 6B is a schematic cross-sectional view of another preferred embodiment of the micropump of the present invention.

Fig. 6C to 6E are schematic operation diagrams of the micro pump in fig. 6A.

Fig. 7 is an exploded view of the components of the blower micro pump.

Fig. 8A to 8C are schematic views illustrating the operation of the blower micro-pump.

Description of the reference numerals

1: tactile sensation detector

2: bra body

21: support structure

22: cup structure

22 a: first cup

22 b: second cup

22 c: center part

22 d: outer surface layer

22 e: inner surface layer

22 f: air bag layer

221 f: convex part structure of air bag

22 g: gas channel

221 g: connecting end

23: fixing structure

24: braces structure

3: gas collection actuator

31: gas conveyer

311: micro pump

3111: intake plate

3111 a: inlet orifice

3111 b: bus bar groove

3111 c: confluence chamber

3112: resonance sheet

3112 a: hollow hole

3112 b: movable part

3112 c: fixing part

3113: piezoelectric actuator

3113 a: suspension plate

3113 b: outer frame

3113 c: support frame

3113 d: piezoelectric element

3113 e: gap

3113 f: convex part

3114: first insulating sheet

3115: conductive sheet

3116: second insulating sheet

3117: chamber space

312: air collecting valve seat

312 a: gas collecting tank

312 b: first gas collection chamber

312 c: first pressure relief chamber

312 d: gas collection through hole

312 e: communicating flow passage

312 f: convex part of air collecting valve seat

312 g: pressure relief through hole

313: cavity plate

313 a: second gas collecting cavity

313 b: second pressure relief chamber

313 c: cavity plate convex part

313 d: communicating chamber

313 e: communicating hole

314: valve plate

314 a: valve bore

315: valve switch

30: air-blast micro pump

301: air injection hole sheet

301 a: connecting piece

301 b: suspension plate

301 c: hollow hole

302: cavity frame

303: actuating body

303 a: piezoelectric carrier plate

303 b: tuning the resonator plate

303 c: piezoelectric plate

304: insulating frame

305: conductive frame

306: resonance chamber

307: airflow chamber

32: control module

33: air pressure detector

A-A': cutting line

Detailed Description

Exemplary embodiments that embody features and advantages of this disclosure are described in detail below in the detailed description. It will be understood that the present invention is capable of various modifications without departing from the scope of the invention, and that the description and drawings are to be regarded as illustrative in nature, and not as restrictive.

Referring to fig. 1, the intelligent brassiere of the present application includes a tactile detector 1, a brassiere body 2 and a gas collection actuator 3. Wherein, the touch detector 1 can sense the change of the surface of the breast, and transmit the detected data to a detection receiving device (such as an application software of a smart phone or a computer) for data analysis, and then transmit the data to the smart medical detector to track the change of the breast and form a notification, if a tumor is generated in the breast, since more blood is gathered at the generated position, the temperature of the breast is increased and the texture is changed, the touch detector 1 can sense the change of the surface of the breast and track the texture, color and temperature of the breast.

The brassiere body 2 includes a supporting structure 21, a cup structure 22, and two sets of fixing structures 23, wherein the supporting structure 21 is mainly used as a connecting component for carrying the cup structure 22 and connecting the two sets of fixing structures 23, the cup structure 22 has a first cup 22a and a second cup 22b which are symmetrically arranged, a central portion 22c is defined between the first cup 22a and the second cup 22b, and each fixing structure 23 is correspondingly disposed on a side of the supporting structure 21 for mutual fastening. Taking this embodiment as an example, the two fixing structures 23 are respectively a corresponding hook structure, but not limited thereto, in some embodiments, the two fixing structures 23 may also be other types of fixing structures, such as two magnets, buttons, button holes, and the like that attract each other, so that the user can wear the intelligent bra of this case on the body. Certainly, the intelligent bra of the present disclosure may further include two sets of strap structures 24 respectively connected to two opposite sides of the supporting structure 21, so that the user can wear the intelligent bra 11 of the present disclosure on the body. In the embodiment, the supporting structure 21 and the strap structure 24 can be cut and sewn by soft cloth, but not limited thereto, and the cup structure 22 can be made of one or more layers of cloth material, which can be changed according to the actual implementation.

Referring to fig. 1 and 2, in the present embodiment, the cup structure 22 is formed by joining and sewing two fabric structures, but not limited thereto, as shown in the figure, it can be seen that the cross-sectional structure of the cup structure 22 of the present embodiment includes an outer surface layer 22d, an inner surface layer 22e and an air bag layer 22f, wherein the air bag layer 22f is sandwiched and covered between the outer surface layer 22d and the inner surface layer 22e, that is, the outer surface layer 22d and the inner surface layer 22e of the present embodiment may be formed by two different fabrics, but not limited thereto, and the material may be changed according to actual implementation. The appearance and arrangement of the air bag layer 22f can be varied in various ways; for example, the air bag layer 22f may be a half-moon arc shape and is correspondingly disposed on the lower edges of the first cup 22a and the second cup 22b, i.e. about 1/3 cups, but not limited thereto; in other embodiments, the bladder layer 22f may also be in the form of 1/2 cups, which cover half of the first cup 22a and the second cup 22b, but not limited thereto; of course, in other embodiments, the bladder layer 22f may be in the form of a complete cup, i.e. it covers the entire first cup 22a and the second cup 22b, so that the form and the position, the range, etc. of the bladder layer 22f can be changed according to the practical implementation situation, and is not limited to the foregoing implementation forms. In addition, as shown in fig. 2, in the present embodiment, the air bag layer 22f further includes an air channel 22g, and is communicated with the air bag layer 22f, the air channel 22g may be disposed in the air bag layer 22f, and the connection end 221g thereof may extend to the central portion 22c of the cup structure 22 and penetrate through the outer surface layer 22d of the cup structure 22 for being connected with the air collection actuator 3, but the arrangement manner is not limited thereto, and in some embodiments, the connection end 221g of the air channel 22g may also be disposed at any position on the cup structure 22, such as the side edge of the first cup 22a or the second cup 22b, and neither is limited thereto, and it may be changed correspondingly according to the position of the air collection actuator 3 to be connected. In the present embodiment, the air collecting actuator 3 is correspondingly disposed at the central portion 22c of the cup structure 22 and detachably connected to the connection end 221g of the air channel 22g of the air bag layer 22f of the cup structure 22, but not limited thereto; in other embodiments, the gas collection actuator 3 may also be a fixed structure and is connected to the connection end 221g of the gas channel 22g, but the arrangement is not limited thereto. Therefore, the gas collection actuator 3 can input or output gas through the connecting end 221g of the gas channel 22g, and further can inflate or exhaust the airbag layer 22f, and adjust the internal pressure of the airbag layer 22f, so that a user can adjust the airbag layer 22f in the cup structure 22 through the gas collection actuator 3, and the softness, appearance form, support strength and the like of the first cup 22a and the second cup 22b can be achieved, and the effect of supporting and lifting can be achieved by optionally adjusting according to the ideal form required by each user. Certainly, the tactile detector 1 of the present disclosure is disposed and attached on the inner surface 22e of the cup structure 22, and the air bag layer 22f adjusts the internal pressure through the air collecting actuator 3, so that the first cup 22a and the second cup 22b can push the tactile detector 1 to adjust according to the shape of the breast, and are further attached to the surface of the breast for detection, thereby improving the detection accuracy of the tactile detector 1.

Please refer to fig. 3, which is a schematic cross-sectional view illustrating an intelligent bra according to another preferred embodiment of the present disclosure. As shown in the figure, in the present embodiment, the main structure of the cup structure 22 of the intelligent bra 2 is the same as that of the preferred embodiment shown in fig. 2, and also includes an outer surface layer 22d, an inner surface layer 22e, and an air bag layer 22f, and the arrangement and connection relationship of these elements are the same as those of the preferred embodiment shown in fig. 2, and therefore, the description thereof is omitted. In this embodiment, the air bag layer 22f of the intelligent bra of the present invention further includes a plurality of air bag protrusion structures 221f, the plurality of air bag protrusion structures 221f are disposed on the inner surface layer 22e of the cup structure 22 and distributed over the first cup 22a and the second cup 22b, but not limited thereto. In addition, the plurality of air bag protrusion structures 221f of the present embodiment are communicated with the air bag layer 22f, so that the air bag layer 22f can be inflated and deflated through the air collection actuator 3 to adjust the pressure, so that the touch feeling of the plurality of air bag protrusion structures 221f is changed, for example, the pressure is increased to harden the plurality of air bag protrusion structures 221f, the touch feeling detector 1 can be pushed to adjust according to the shape of the breast, and the air bag protrusion structures are more attached to the surface of the breast for detection, so as to improve the detection accuracy of the touch feeling detector 1.

The gas collection actuator 3 is disposed in the gas passage 22g connected to the air bag layer 22f for delivering gas to adjust the internal pressure of the air bag layer 22f, and the gas collection actuator 3 includes a gas delivery device 31, a control module 32 and a pressure detector 33. The control module 32 controls the opening and closing operations of the gas conveyer 31 and controls the set threshold mode of the gas pressure detector 33, and the gas pressure detector 33 detects the internal gas pressure required by the air bag layer 22f, and when the internal gas pressure reaches the set threshold, the control module 32 is immediately notified to control the closing operation of the gas conveyer 31, so as to achieve an intelligent control setting. That is, the user can control the set threshold mode of the air pressure detector 33 through the control module 32, so that the user can properly adjust the set threshold of the inflation amount of the air bag layer 22f in the cup structure 22 to control the operation time of opening and closing the air conveyor 31, so that the softness, appearance, support strength, etc. of the first cup 22a and the second cup 22b can meet the requirements of the user, thereby achieving the intelligent power-saving control.

Referring to fig. 2, fig. 3 and fig. 4A to fig. 4D, the gas delivery device 31 is connected to the connection end 221g of the gas channel 22g, and includes a micro pump 311, a gas collecting valve seat 312, a cavity plate 313, a valve plate 314 and a valve switch 315. Wherein the gas collecting valve seat 312 is concavely provided with a gas collecting groove 312a on one surface for communicating with the connecting end 221g of the gas channel 22g, and a first gas collecting chamber 312b and a first pressure relief chamber 312c on the other surface, a gas collecting through hole 312d is provided between the gas collecting groove 312a and the first gas collecting chamber 312b for communicating the gas collecting groove 312a and the first gas collecting chamber 312b with each other, the first gas collecting chamber 312b and the first pressure relief chamber 312c are provided at a distance from each other on the other surface of the gas collecting valve seat 312, a communicating flow passage 312e is provided between the first gas collecting chamber 312b and the first pressure relief chamber 312c for communicating the first gas collecting chamber 312b and the first pressure relief chamber 312c with each other, a gas collecting valve seat convex part 312f is provided in the first pressure relief chamber 312c, and a pressure relief through hole 312g is provided in the center of the valve seat convex part 312f, the pressure relief through hole 312g communicates with the first pressure relief chamber 312c and the valve switch 315, the valve switch 315 is a switch for controlling the pressure relief through hole 312g to exhaust gas, and the valve switch 315 is controlled by the control module 32 to be turned on or off, and the gas collecting channel 312a is communicated and sealed with the connecting end 221g of the gas channel 22g as shown in fig. 2 and 3, so that the air bag layer 22f is communicated with the gas collecting channel 312a and the gas collecting through hole 312 d; the cavity plate 313 is supported on the air collecting valve seat 312, and a second air collecting chamber 313a and a second pressure relief chamber 313b are respectively arranged on the surface of the air collecting valve seat 312, wherein the surface of the second air collecting chamber 313a and the surface of the first pressure relief chamber 312b are correspondingly covered, the surface of the second air collecting chamber 313a and the surface of the first pressure relief chamber 312c are correspondingly covered, a cavity plate convex part 313c is arranged in the second air collecting chamber 313a, a communication chamber 313d is concavely arranged on the surface of the cavity plate 313a and the surface of the second pressure relief chamber 313b, the micro pump 311 is supported on the cavity plate 313 to cover the communication chamber 313d, and the communication chamber 313d penetrates through at least one through hole 313e and is respectively communicated with the second air collecting chamber 313a and the second pressure relief chamber 313 b; furthermore, the valve plate 314 is disposed between the air collecting valve seat 312 and the cavity plate 313, the valve plate 314 abuts against the air collecting valve seat protrusion 312f to close the pressure relief through hole 312g, a valve hole 314a is disposed at a position where the valve plate 314 abuts against the cavity plate protrusion 313c, and the valve hole 314a is closed by abutting against the cavity plate protrusion 313 c.

Referring to fig. 5A to 5B and fig. 6A to 6E, the micro pump 311 is formed by sequentially stacking a current inlet plate 3111, a resonant plate 3112, a piezoelectric actuator 3113, a first insulating plate 3114, a conductive plate 3115 and a second insulating plate 3116.

The flow inlet plate 3111 has at least one inlet hole 3111a, at least one bus groove 3111b and a bus chamber 3111c, the inlet hole 3111a is used for introducing gas, the inlet hole 3111a correspondingly penetrates through the bus groove 3111b, and the bus groove 3111b is communicated with the bus chamber 3111c, so that the gas introduced by the inlet hole 3111a can be merged into the bus chamber 3111 c. In this embodiment, the number of the inflow holes 3111a and the number of the bus grooves 3111b are the same, the number of the inflow holes 3111a and the number of the bus grooves 3111b are 4 respectively, and the number of the inflow holes 3111a and the number of the bus grooves 3111b are not limited thereto, 4 inflow holes 3111a penetrate 4 bus grooves 3111b respectively, and 4 bus grooves 3111b are converged into the bus chamber 3111 c.

The resonator plate 3112 is coupled to the flow inlet plate 3111 by a bonding method, and the resonator plate 3112 has a hollow hole 3112a, a movable portion 3112b and a fixing portion 3112c, the hollow hole 3112a is located at the center of the resonator plate 3112 and corresponds to the flow collecting chamber 3111c of the flow inlet plate 3111, the movable portion 3112b is disposed around the hollow hole 3112a and in a region opposite to the flow collecting chamber 3111c, and the fixing portion 3112c is disposed at the outer peripheral edge portion of the resonator plate 3112 and is bonded to the flow inlet plate 3111.

The piezoelectric actuator 3113 includes a suspension plate 3113a, a frame 3113b, at least one support 3113c, a piezoelectric element 3113d, at least one gap 3113e and a protrusion 3113 f; wherein, the suspension plate 3113a is a square type, the suspension plate 3113a is square, compared with the design of a circular suspension plate, the structure of the square suspension plate 3113a has the advantage of power saving obviously, because of the capacitive load operated under the resonant frequency, the consumed power will increase along with the frequency rise, and because the resonant frequency of the square suspension plate 3113a is obviously lower than that of the circular suspension plate, the relative consumed power is also obviously lower, that is, the suspension plate 3113a designed by the square has the benefit of power saving; the outer frame 3113b is disposed around the suspension plate 3113 a; at least one support 3113c is connected between the suspension plate 3113a and the outer frame 3113b to provide a supporting force for elastically supporting the suspension plate 3113 a; and a piezoelectric element 3113d having a side length less than or equal to a side length of the suspension plate 3113a, and the piezoelectric element 3113d is attached on a surface of the suspension plate 3113a for being applied with a voltage to drive the suspension plate 3113a to vibrate in a bending manner; at least one gap 3113e is formed between the suspension plate 3113a, the outer frame 3113b and the support 3113c for passing gas; the protrusion 3113f is disposed on the opposite surface of the suspension plate 3113a to which the piezoelectric element 3113d is attached, and in this embodiment, the protrusion 3113f may be a convex structure integrally formed on the opposite surface of the suspension plate 3113a to which the piezoelectric element 3113d is attached through an etching process.

The above-mentioned flow inlet plate 3111, resonator plate 3112, piezoelectric actuator 3113, first insulating plate 3114, conducting plate 3115 and second insulating plate 3116 are stacked and combined in sequence, wherein a cavity space 3117 is required to be formed between the suspension plate 3113a and the resonator plate 3112, the cavity space 3117 can be formed by filling a material in a gap between the resonator plate 3112 and the outer frame 3113b of the piezoelectric actuator 3113, for example: the conductive adhesive, but not limited thereto, can maintain a certain depth between the resonator plate 3112 and the suspension plate 3113a to form a cavity space 3117, so as to guide the gas to flow more rapidly, and since the suspension plate 3113a and the resonator plate 3112 maintain a proper distance to reduce the mutual contact interference, the noise generation can be reduced, in an embodiment, the height of the outer frame 3113b of the piezoelectric actuator 3113 can be increased to reduce the thickness of the conductive adhesive filled in the gap between the resonator plate 3112 and the outer frame 3113b of the piezoelectric actuator 3113, so as to avoid the influence of the conductive adhesive on the actual distance of the cavity space 3117 after molding due to thermal expansion and contraction, and reduce the indirect influence of the thermal compression temperature and the cooling temperature of the conductive adhesive on the overall assembly structure of the micro pump 311, but not limited thereto. In addition, the chamber space 3117 will affect the transfer efficiency of the micro-pump, so it is important to maintain a fixed chamber space 3117 for providing stable transfer efficiency of the micro-pump.

Thus, as shown in fig. 6B, in other embodiments of the piezoelectric actuator 3113, the suspension plate 3113a may be stamped and formed to extend outwardly a distance that is adjustable by at least one bracket 3113c formed between the suspension plate 3113a and the housing 3113B such that the surface of the protrusion 3113f on the suspension plate 3113a and the surface of the housing 3113B are both non-coplanar, utilizing a small amount of filler material applied to the mating surface of the housing 3113B, such as: the conductive adhesive is thermally pressed to attach the piezoelectric actuator 3113 to the fixing portion 3112c of the resonator plate 3112, so that the piezoelectric actuator 3113 can be assembled with the resonator plate 3112, and thus the required cavity space 3117 can be achieved by adjusting the press forming distance of the suspension plate 3113a of the piezoelectric actuator 3113 through the structural improvement of forming the cavity space 3117 by pressing the suspension plate 3113a of the piezoelectric actuator 3113, thereby effectively simplifying the structural design of the cavity space 3117, simplifying the manufacturing process, and shortening the manufacturing process time. In addition, the first insulating sheet 3114, the conductive sheet 3115 and the second insulating sheet 3116 are frame-shaped thin sheet bodies, and are sequentially stacked on the piezoelectric actuator 3113 to form the overall structure of the micro-pump 311.

To understand the output operation of the micro pump 311 for gas transmission, please refer to fig. 6C to 6E. Referring to fig. 6C, after the piezoelectric element 3113d of the piezoelectric actuator 3113 is applied with a driving voltage, the floating plate 3113a is deformed to move downward, and at this time, the volume of the chamber space 3117 is increased, a negative pressure is formed in the chamber space 3117, so that the gas in the bus chamber 3111C is drawn into the chamber space 3117, and the resonance plate 3112 is synchronously moved downward under the influence of the resonance principle, thereby increasing the volume of the bus chamber 3111C, and the gas in the bus chamber 3111C is also in a negative pressure state due to the relationship that the gas in the bus chamber 3111C enters the chamber space 3117, so that the gas is sucked into the bus chamber 3111C through the inlet hole 3111a and the bus groove 3111 b; referring to fig. 6D, the piezoelectric element 3113D drives the floating plate 3113a to move upward to compress the chamber space 3117, and similarly, the resonant plate 3112 moves upward due to resonance with the floating plate 3113a to force the gas in the chamber space 3117 to be pushed downward through the gap 3113e, so as to achieve the effect of gas transmission; finally, referring to fig. 6E, when the suspension plate 3113a is driven downward, the resonator plate 3112 is driven to displace downward, and the resonator plate 3112 moves the gas in the compression chamber space 3117 to the gap 3113E and raises the volume in the bus chamber 3111c, so that the gas can continuously pass through the inlet hole 3111a and the bus groove 3111b to be collected in the bus chamber 3111 c. By repeating the operation steps of gas transmission provided by the micro pump 311 shown in fig. 6C to 6E, the micro pump 311 can continuously introduce gas from the inlet hole 3111a into the flow channel formed by the inlet plate 3111 and the resonator plate 3112 to generate a pressure gradient, and then transmit the gas downwards through the gap 3113E to make the gas flow at a high speed, so as to achieve the operation of gas output transmission of the micro pump 311.

Referring to fig. 6A, the inlet plate 3111, the resonator plate 3112, the piezoelectric actuator 3113, the first insulating plate 3114, the conductive plate 3115 and the second insulating plate 3116 of the micro-pump 311 can be processed by micro-electromechanical surface micromachining to reduce the volume of the micro-pump 311, so as to form the micro-pump 311 of the mems.

As can be seen from the above description, referring to fig. 4B and 4C, the micro pump 311 is controlled by the control module 32 to drive the gas to be guided and delivered to the communicating chamber 313d to be concentrated, and then guided from the communicating chamber 313d to the second gas collecting chamber 313a and the second pressure relief chamber 313B through the communicating hole 313e, so as to push the valve plate 314 away from the cavity plate protrusion 313C, so that the gas is guided into the first gas collecting chamber 312B through the valve hole 314a of the valve plate 314 and concentrated into the gas collecting groove 312a through the gas collecting through hole 312d, and the gas simultaneously pushes the valve plate 314 to abut against the gas collecting valve seat protrusion 312f to close the pressure relief through hole 312g, while the gas in the second pressure relief chamber 313B is guided into the second gas collecting chamber 313a through the communicating channel 312e, and guided into the first gas collecting chamber 312B through the valve hole 314a of the valve plate 314 and concentrated into the gas collecting groove 312a through the gas collecting through hole 312d, so that the gas is filled in the air bag layer 22f (as shown in fig, to form an inflation operation of the air bag layer 22f and to adjust the internal pressure of the air bag layer 22 f; as shown in fig. 4D, when the micro pump 311 stops conducting gas, the charging pressure in the air bag layer 22f (as shown in fig. 2) is greater than the gas pressure in the communicating chamber 313D, at this time, the gas-collecting gas in the air bag layer 22f pushes the valve plate 314 to displace and touch the cavity plate protrusion 313c to close the valve hole 314a, and pushes the valve plate 314 to leave and touch the gas-collecting valve seat protrusion 312f to open the pressure-releasing through hole 312g, and the valve switch 315 is controlled by the control module 32 to open and control the air-discharging of the pressure-releasing through hole 312g, so that the charging gas in the air bag layer 22f is guided out of the communicating flow passage 312e to the pressure-releasing through hole 312g and discharged to the outside of the gas conveyor 31, thereby completing the pressure-releasing operation of the.

The intelligent bra of the present application can deliver gas to the gas channel 22g through the continuous operation of the gas delivery device 31 of the gas collection actuator 3, and then introduce the gas into the air bag layer 22f to form inflation, wherein, of course, the gas volume in the air bag layer 22f can be monitored through the set threshold mode of the gas pressure detector 33, and the control module 32 is used to control the valve switch 315 of the gas delivery device 31 to open or close the operation, so that the gas delivery device 31 continuously operates to deliver gas to the gas channel 22g, and is stored through the closing operation of the valve switch 315, and is monitored through the set threshold mode of the gas pressure detector 33 to adjust the proper inflation volume of the air bag layer 22f in the cup structure 22, and when the inflation volume reaches the set threshold of the gas pressure detector 33, the micro pump 311 of the gas delivery device 31 can immediately stop operating; when the inflation amount of the airbag layer 22f in the cup structure 22 is insufficient, the user can control the set threshold mode of the air pressure detector 33 through the control module 32 to properly adjust the set threshold of the inflation amount of the airbag layer 22f, and the micro pump 311 of the air conveyor 31 is controlled by the control module 32 to start and operate to control the operation time of the micro pump 311, so as to control the operation time of the micro pump 311 to start and close, so that the softness, appearance and support strength of the first cup 22a and the second cup 22b meet the requirement of the user, and the intelligent power-saving control is achieved. Certainly, the tactile detector 1 of the present disclosure is disposed and attached on the inner surface 22e of the cup structure 22, and the air bag layer 22f adjusts the internal pressure through the air collecting actuator 3, so that the first cup 22a and the second cup 22b can push the tactile detector 1 to adjust according to the shape of the breast, and are further attached to the surface of the breast for detection, thereby improving the detection accuracy of the tactile detector 1.

In addition to the micro pump 311, the gas delivery unit 31 may also be configured with a blower micro pump 30 to deliver gas. Referring to fig. 7 and 8A to 8C, the blower micro-pump 30 includes a gas injection hole plate 301, a cavity frame 302, an actuator 303, an insulating frame 304 and a conductive frame 305 stacked in sequence; the air hole plate 301 includes a plurality of connecting members 301a, a floating plate 301b and a hollow hole 301c, the floating plate 301b can be bent and vibrated, the connecting members 301a are adjacent to the periphery of the floating plate 301b, in this embodiment, the number of the connecting members 301a is 4, and the connecting members are respectively adjacent to 4 corners of the floating plate 301b, but not limited thereto; a hollow hole 301c is formed in the center of the suspension plate 301 b; the cavity frame 302 is carried and superposed on the suspension plate 301 b; the actuating body 303 is stacked on the cavity frame 302, and comprises a piezoelectric carrier plate 303a, an adjusting resonator plate 303b and a piezoelectric plate 303c, wherein the piezoelectric carrier plate 303a is stacked on the cavity frame 302, the adjusting resonator plate 303b is stacked on the piezoelectric carrier plate 303a, the piezoelectric plate 303c is stacked on the adjusting resonator plate 303b, and deforms to drive the piezoelectric carrier plate 303a and the adjusting resonator plate 303b to perform reciprocating bending vibration after voltage is applied; the insulating frame 304 is carried and overlapped on the piezoelectric carrier plate 303a of the actuating body 303, and the conductive frame 305 is carried and overlapped on the insulating frame 304, wherein a resonant cavity 306 is formed among the actuating body 303, the cavity frame 302 and the suspension plate 301 b.

Please refer to fig. 8A to 8C, which are operation diagrams of the blower micro-pump 30 of the present disclosure. Referring to fig. 7 and fig. 8A, the blower micro pump 30 is fixedly disposed through a plurality of connecting members 301a, and an airflow chamber 307 is formed at the bottom of the air injection hole piece 301; referring to fig. 8B, when a voltage is applied to the piezoelectric plate 303c of the actuating body 303, the piezoelectric plate 303c begins to deform due to the piezoelectric effect and synchronously drives the adjustment resonance plate 303B and the piezoelectric support plate 303a, at this time, the air hole plate 301 is driven by Helmholtz resonance (Helmholtz resonance) principle, so that the actuating body 303 moves upward, and as the actuating body 303 moves upward, the volume of the airflow chamber 307 at the bottom of the air hole plate 301 is increased, the internal air pressure forms a negative pressure, and the air outside the blower micro pump 30 enters the airflow chamber 307 through the gap of the connecting member 301a of the air hole plate 301 due to the pressure gradient and is collected; finally, referring to fig. 8C, the gas continuously enters the gas flow chamber 307 to form a positive pressure in the gas flow chamber 307, and at this time, the actuating body 303 is driven by the voltage to move downward, so as to compress the volume of the gas flow chamber 307 and push the gas in the gas flow chamber 307, so that the gas enters the blower micro pump 30 and is discharged, thereby realizing the transmission flow of the gas.

The blower micro-pump 30 can also be a mems gas pump fabricated by a mems process, in which the air hole plate 301, the cavity frame 302, the actuator 303, the insulating frame 304 and the conductive frame 305 can be fabricated by a surface micro-machining technique to reduce the volume of the blower micro-pump 30.

In conclusion, the present disclosure provides an intelligent bra, which utilizes a gas collection actuator to cooperate with a bladder layer disposed in a cup structure, inflates or deflates the bladder layer in the cup structure by a gas conveyor of the gas collection actuator, and sets a threshold mode to monitor and adjust the proper inflation amount of the bladder layer in the cup structure in cooperation with a pressure detector of the gas collection actuator, so as to adjust the pressure in the bladder layer, and can utilize the pressure change therein to change the shape, hardness, and support strength of a first cup and a second cup on the cup structure, thereby allowing a user to adjust the intelligent bra according to his own needs, so as to achieve the effects of stable support and lifting, and to attach a touch detector of a breast to the cup structure, and to push the touch detector to attach to the breast surface according to the breast shape adjustment by the bladder layer to detect, so as to improve the detection accuracy of the touch detector, so that the intelligent bra of the present case can meet different requirements of each user. Therefore, the present application has industrial application value, and application is made by the following methods.

Various modifications may be made by those skilled in the art without departing from the scope of the invention as defined by the appended claims.

Claims (18)

1. An intelligent bra, comprising:

a bra body, comprising a supporting structure, a cup structure and two groups of fixing structures, wherein the supporting structure is used for bearing the cup structure and is connected with the two groups of fixing structures, each fixing structure is respectively and correspondingly arranged on one side of the supporting structure and is used for being buckled with each other, the cup structure comprises an outer surface layer, an inner surface layer and an air bag layer, the air bag layer is coated between the outer surface layer and the inner surface layer, the air bag layer comprises an air channel, the air channel is provided with a connecting end, and the connecting end penetrates out of the cup structure; and

the gas collection actuator is connected to the connecting end of the gas channel and comprises a gas conveyer, a control module and a gas pressure detector, wherein the gas conveyer is used for supplying gas to the air bag layer in the cup structure to adjust the internal pressure, the control module is used for controlling the operation of the gas conveyer and controlling the set threshold value mode of the gas pressure detector, and the gas pressure detector is used for detecting the internal gas pressure required by the air bag layer so as to monitor and inform the control module to control the operation of the gas conveyer.

2. The intelligent bra of claim 1, further comprising a tactile detector attached to the inner surface of the cup structure, wherein the air collection actuator adjusts the internal pressure of the air bag layer to push the tactile detector to attach to the bra for detection, thereby improving the detection accuracy of the tactile detector.

3. The intelligent bra of claim 1, further comprising a tactile detector, wherein the airbag layer comprises a plurality of airbag protrusion structures disposed on the inner surface of the cup structure, and the tactile detector is disposed and attached to the plurality of airbag protrusion structures, and the gas collection actuator adjusts the internal pressure of the airbag layer to enable the plurality of airbag protrusion structures of the airbag layer to push the tactile detector to attach and detect, so as to improve the detection accuracy of the tactile detector.

4. The intelligent bra of claim 1, wherein the cup structure has a first cup and a second cup symmetrically disposed, and a central portion is defined between the first cup and the second cup, and the air channel is disposed in the bladder layer, and the connecting end of the air channel extends to the central portion and out of the outer skin of the cup structure for connection to the air collection actuator.

5. The intelligent brassiere according to claim 1, wherein said gas conveyor comprises a micropump, a gas collecting valve seat, a cavity plate, a valve plate and a valve switch, wherein said gas collecting valve seat is supported in said brassiere body, and has a gas collecting groove recessed in one surface thereof for communicating with said connecting end of said gas passage, and a first gas collecting chamber and a first pressure relief chamber formed in the other surface thereof, a gas collecting through hole is formed between said gas collecting groove and said first gas collecting chamber for communicating said gas collecting groove and said first gas collecting chamber with each other, said first gas collecting chamber and said first pressure relief chamber are spaced apart from each other on the other surface of said gas collecting valve seat, and a communicating flow passage is formed between said first gas collecting chamber and said first pressure relief chamber for communicating said first gas collecting chamber and said first pressure relief chamber with each other, said first pressure relief chamber having a gas collecting valve seat protrusion therein, the center of the convex part of the gas collecting valve seat is provided with a pressure relief through hole which is communicated with the first pressure relief chamber and is communicated with the valve switch, the valve switch is a switch for controlling the exhaust of the pressure relief through hole, the valve switch is controlled by the control module to operate, the cavity plate is supported on the gas collecting valve seat, the upper surface corresponding to the gas collecting valve seat is respectively provided with a second gas collecting chamber which is mutually corresponding to the first gas collecting chamber and is sealed and covered with the first pressure relief chamber, the second gas collecting chamber is internally provided with a cavity plate convex part, the other surface of the cavity plate corresponding to the second gas collecting chamber and the second pressure relief chamber is concavely provided with a communicating chamber, the micro pump is supported on the cavity plate and is sealed and covered with the communicating chamber, and the communicating chamber is communicated with the second gas collecting chamber and the second pressure relief chamber through at least one connecting through hole, the valve plate is arranged between the gas collecting valve seat and the cavity plate to abut against the convex part of the gas collecting valve seat to seal the pressure relief through hole, and a valve hole is arranged at the position abutting against the convex part of the cavity plate and is sealed by abutting against the convex part of the cavity plate.

6. The intelligent bra of claim 5, wherein the micro pump is controlled by the control module to drive and conduct gas to the communicating chamber for concentration, then the gas is guided into the second gas collecting chamber and the second pressure relief chamber from the communicating chamber through the communicating hole, so as to push the valve plate to leave the cavity plate convex part and lead the gas to be continuously led into the first gas collecting cavity through the valve hole of the valve plate, and is concentrated into the gas collecting tank through the gas collecting through hole, and the gas simultaneously pushes the valve plate to abut against the convex part of the gas collecting valve seat to seal the pressure relief through hole, the gas in the second pressure relief chamber is guided into the second gas collecting chamber from the communicating flow passage and is continuously guided into the first gas collecting chamber through the valve hole of the valve plate, and the gas is concentrated into the gas collecting groove through the gas collecting through hole, so that the gas is filled in the air bag layer to form the air inflation operation of the air bag layer.

7. The intelligent bra of claim 5, wherein when the micro pump stops delivering gas, the inflation pressure in the air bag layer is greater than the gas pressure at the communicating chamber, and at this time, the gas collecting gas in the air bag layer can push the valve plate to displace against the cavity plate protrusion to close the valve hole, and push the valve plate to leave against the gas collecting valve seat protrusion to open the pressure relief through hole, and the valve switch control module opens to control the exhaust of the pressure relief through hole, so that the inflation gas in the air bag layer is guided out of the communicating channel into the pressure relief through hole and discharged outside the gas conveyor, thereby completing the pressure relief operation of the air bag layer.

8. The intelligent bra of claim 5, wherein the micropump comprises:

the inflow plate is provided with at least one inflow hole, at least one bus groove and a confluence chamber, wherein the inflow hole is used for introducing gas, the inflow hole correspondingly penetrates through the bus groove, and the bus groove is communicated with the confluence chamber, so that the gas introduced by the inflow hole can be converged into the confluence chamber;

a resonance sheet, which is combined on the flow inlet plate and is provided with a hollow hole, a movable part and a fixed part, wherein the hollow hole is positioned at the center of the resonance sheet and corresponds to the confluence chamber of the flow inlet plate, the movable part is arranged around the hollow hole and is arranged in the area opposite to the confluence chamber, and the fixed part is arranged at the outer peripheral part of the resonance sheet so as to be attached and fixed on the flow inlet plate; and

a piezoelectric actuator combined on the resonance sheet and arranged correspondingly;

when the piezoelectric actuator is driven, introduced gas enters from the inflow hole of the inflow plate, is collected into the confluence chamber through the bus groove, passes through the hollow hole of the resonance sheet, and resonates with the movable part of the resonance sheet by the piezoelectric actuator to conduct gas to be output.

9. The intelligent bra of claim 8, wherein the piezoelectric actuator comprises:

the suspension plate is in a square shape and can be bent and vibrated;

an outer frame surrounding the suspension plate;

at least one bracket connected between the suspension plate and the outer frame to provide elastic support for the suspension plate; and the piezoelectric element is attached to one surface of the suspension plate and used for applying voltage to drive the suspension plate to vibrate in a bending mode.

10. The intelligent bra of claim 8, wherein the micro pump further comprises a first insulating plate, a conducting plate and a second insulating plate, wherein the intake plate, the resonator plate, the piezoelectric actuator, the first insulating plate, the conducting plate and the second insulating plate are sequentially stacked and combined.

11. The intelligent bra of claim 9, wherein the suspension plate comprises a protrusion disposed on the other surface of the suspension plate opposite to the surface of the suspension plate attached to the piezoelectric element.

12. The intelligent bra of claim 11, wherein the convex portion is integrally formed by etching to protrude from the suspension plate and is attached to the other surface of the piezoelectric element opposite to the surface of the piezoelectric element to form a convex structure.

13. The intelligent bra of claim 8, wherein the piezoelectric actuator comprises:

the suspension plate is in a square shape and can be bent and vibrated;

an outer frame surrounding the suspension plate;

at least one bracket, which is connected and formed between the suspension plate and the outer frame to provide the suspension plate with elastic support, and a surface of the suspension plate and a surface of the outer frame form a non-coplanar structure, and a cavity space is kept between the surface of the suspension plate and the resonance plate; and

the piezoelectric element is attached to one surface of the suspension plate and used for applying voltage to drive the suspension plate to vibrate in a bending mode.

14. The intelligent bra of claim 5, wherein the micropump is a microelectromechanical system micropump.

15. The intelligent bra of claim 5, wherein the micropump is an air-moving micropump, the air-moving micropump comprising:

the suspension plate is fixedly arranged through the connecting pieces, the connecting pieces provide elastic support for the suspension piece, an air flow chamber is formed between the bottoms of the air injection hole pieces, and at least one gap is formed between the connecting pieces and the suspension piece;

a cavity frame bearing and superposed on the suspension plate;

an actuating body bearing and overlapping on the cavity frame to receive voltage to generate reciprocating bending vibration;

an insulating frame bearing and superposed on the actuating body; and

a conductive frame, which is arranged on the insulating frame in a bearing and stacking manner;

wherein, a resonance chamber is formed among the actuating body, the cavity frame and the suspension sheet, and the suspension sheet of the air injection hole sheet generates reciprocating vibration displacement by driving the actuating body to drive the air injection hole sheet to generate resonance, so that the gas enters the airflow chamber through the gap and is discharged, and the transmission flow of the gas is realized.

16. The intelligent bra of claim 15, wherein the actuating body comprises:

a piezoelectric carrier plate bearing and superposed on the cavity frame;

the adjusting resonance plate is loaded and stacked on the piezoelectric carrier plate; and

and the piezoelectric plate is loaded and stacked on the adjusting resonance plate to receive voltage to drive the piezoelectric carrier plate and the adjusting resonance plate to generate reciprocating bending vibration.

17. The intelligent bra of claim 5, wherein the micro pump of the gas delivery device is continuously operated to deliver gas to the gas channel and then introduced into the air bag layer to form inflation, the inflation amount in the air bag layer is monitored by the set threshold mode of the pressure detector, and the control module is used to control the operation of the valve switch of the gas delivery device, so that the gas in the air bag layer is preserved, the set threshold of the pressure detector is used to monitor and adjust the proper inflation amount of the air bag layer, and when the set threshold of the pressure detector is reached, the micro pump can stop operating instantly.

18. The intelligent bra of claim 17, wherein when the inflation amount of the air bag layer is insufficient, the user controls the set threshold mode of the air pressure detector through the control module to properly adjust the set threshold of the inflation amount of the air bag layer, and the micro pump of the air conveyor is controlled by the control module to start operation to control the operation time of the micro pump.

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