CN215531697U - Intelligent bra - Google Patents

Abstract

The utility model relates to the technical field of intelligent wearing, and provides an intelligent bra which comprises a bra body, a vibration module, a heating module, a sensing module, a control module and a power supply module. The vibration module, the heating module, the sensing module, the control module and the power supply module are respectively arranged on the bra body, and the control module is respectively connected with the vibration module, the heating module, the sensing module and the power supply module. The vibrating device can vibrate to work in order to massage the user, heating device can heat work in order to improve local blood circulation, human physiological signal can be gathered to sensing device, controlling means can handle this physiological signal of analysis and send for the user, help the user to know individual physical and mental health situation comprehensively, and the physiological signal control vibrating device and the heating device work of gathering through sensing device, can realize alleviating user's uncomfortable through vibrating device and heating device.

Description

Intelligent bra

[ technical field ] A method for producing a semiconductor device

The utility model relates to the technical field of intelligent wearing, in particular to an intelligent bra.

[ background of the utility model ]

At present, the physical and mental health problems of women are becoming the focus of general social attention, and various wearable devices for detecting the physical and mental health of women are born at present. The brassiere is as women's daily indispensable articles for daily use, can combine together with physiological signal sensing equipment, detects the physiological parameter of women's daily work time. At present, the intelligent bra capable of detecting the human physiological parameters focuses on detecting the physiological state of the female in the movement process, can assist the female to realize the best movement effect, and provides guarantee for the healthy movement of the female. However, after the bra is worn for a long time in the daily life of the female, the blood in the chest is not circulated, and the discomfort can be caused.

[ Utility model ] content

In order to solve the above technical problems, embodiments of the present invention provide an intelligent bra, which can provide a massage function and a heating function, so that a user can relax effectively.

The embodiment of the utility model adopts the following technical scheme for solving the technical problems:

provide an intelligent brassiere, include:

a bra body;

the vibration module is arranged on the bra body;

the heating module is arranged on the bra body;

the sensing module is arranged on the bra body and is used for acquiring physiological signals of a user;

the control module is arranged on the bra body, is respectively connected with the vibration module, the heating module and the sensing module, and is used for receiving and processing physiological signals acquired by the sensing module and respectively controlling the vibration module and the heating module to work;

the power supply module is arranged on the bra body and connected with the control module, and the power supply module is used for supplying power to the vibration module, the heating module, the sensing module and the control module respectively.

Optionally, the vibration module includes a first vibration module, the first vibration module includes a plurality of first vibration motors, and the plurality of first vibration motors are arranged at intervals.

Optionally, the vibration module further includes a second vibration module, and the second vibration module and the first vibration module are arranged at an interval;

the second vibration module comprises a plurality of second vibration motors which are arranged at intervals.

Optionally, the first vibration motors are arranged at intervals in a U shape; and/or

The plurality of second vibrating motors are arranged at intervals in a U shape.

Optionally, the heating device includes a heating plate, and the heating plate is disposed between the first vibration module and the second vibration module.

Optionally, the bra body comprises a lower scrabbling belt and two cup bodies, and the two cup bodies are respectively connected to the lower scrabbling belt;

the vibration module and the heating module are respectively arranged on the two cup bodies, and the sensing module, the control module and the power supply module are respectively arranged on the lower scrabbling belt.

Optionally, the sensing module comprises a micro-electromechanical sensor and a piezoelectric thin film sensor, the micro-electromechanical sensor is electrically connected with the piezoelectric thin film sensor,

the micro-electromechanical sensor is arranged on the front surface of the lower scrabbling belt and is positioned between the two cup bodies;

the piezoelectric film sensor extends from the micro-electromechanical sensor to the back of the lower scrabbling belt;

the micro-electromechanical sensor and the piezoelectric film sensor are respectively used for acquiring physiological signals of a user, and the physiological signals comprise heart rate signals and respiration signals.

Optionally, the control module is arranged on the lower scrabbling belt and comprises a main control unit, a storage unit and a communication unit;

the main control unit is respectively connected with the micro-electromechanical sensor and the piezoelectric film sensor and is used for processing and analyzing physiological signals collected by the micro-electromechanical sensor and the piezoelectric film sensor and calculating effective physiological data;

the storage unit is used for storing the effective physiological data processed by the main control unit

The communication module is used for transmitting the effective physiological data stored in the storage unit to the external electronic equipment.

Optionally, the lower scrabbling belt is provided with a control box, and the control module is arranged in the control box.

Optionally, the power supply module includes a power supply, and the power supply is connected to the main control unit;

the lower scrabbling belt is provided with a power supply box, and the power supply is arranged in the power supply box.

Compared with the prior art, in the embodiment of the utility model, the bra body is further provided with the vibrating device and the heating device, the vibrating device can vibrate to massage a user, the heating device can heat to improve local blood circulation, the bra body is further provided with the sensing device and the control device, the sensing device can collect physiological signals of a human body, the control device can process and analyze the physiological signals and send the physiological signals to the user, the user can be helped to comprehensively know the physical and mental health conditions of the user, the vibrating device and the heating device are controlled to work through the physiological signals collected by the sensing device, and discomfort of the user can be relieved through the vibrating device and the heating device.

[ description of the drawings ]

One or more embodiments are illustrated in drawings corresponding to, and not limiting to, the embodiments, in which elements having the same reference number designation may be represented as similar elements, unless specifically noted, the drawings in the figures are not to scale.

FIG. 1 is a schematic structural view of an intelligent brassiere according to an embodiment of the present invention;

FIG. 2 is a schematic view of another angle of the intelligent brassiere shown in FIG. 1, with some components omitted;

FIG. 3 is a schematic view of another angle of the intelligent brassiere shown in FIG. 1, with some components omitted;

FIG. 4 is a schematic structural view of a cup, a vibration module, and a heating module of the smart bra shown in FIG. 2;

FIG. 5 is a schematic structural view of a cup and a vibration module of the smart bra of FIG. 4, with some components omitted;

FIG. 6 is a schematic structural diagram of a vibration module, a heating module, a sensing module, a control module, and a power supply module of the intelligent bra shown in FIG. 2;

FIG. 7 is a schematic structural diagram of a lower scrabbling belt, a sensing module, a control module, and a power supply module of the intelligent bra shown in FIG. 2, wherein some components are omitted;

fig. 8 is a functional module diagram of the intelligent bra shown in fig. 2.

[ detailed description ] embodiments

In order to facilitate an understanding of the utility model, the utility model is described in more detail below with reference to the accompanying drawings and specific examples. It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may be present. The terms "vertical," "horizontal," "left," "right," "inner," "outer," and the like as used herein are for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Furthermore, the technical features mentioned in the different embodiments of the utility model described below can be combined with each other as long as they do not conflict with each other.

Referring to fig. 1 and 2 together, an embodiment of the present invention provides an intelligent bra 100, which includes a bra main body 10, a vibration module 20, a heating module 30, a sensing module 40, a control module 50, and a power supply module 60. The vibration module 20, the heating module 30, the sensing module 40, the control module 50 and the power supply module 60 are respectively arranged on the bra main body 10, and the control module 50 is respectively electrically connected with the vibration module 20, the heating module 30, the sensing module 40 and the power supply module 60. The vibration module 20 is used for generating vibration to massage, the heating module 30 is used for generating heat to heat, the sensing module 40 is used for collecting physiological signals of a user, the control module 50 is used for receiving and processing the physiological signals collected by the sensing module 40, the control module 50 respectively controls the vibration module 20 and the heating module 30 to work, and the power supply module 60 respectively supplies power to the vibration module 20, the heating module 30, the sensing module 40 and the control module 50.

Referring to fig. 2 and 3, the brassiere body 10 is made of a soft and elastic fabric material, the brassiere body 10 includes a cup body 11, a lower pulling strap 12 and a shoulder strap 13, and the lower pulling strap 12 and the shoulder strap 13 are respectively connected to the cup body 11.

The number of the cup bodies 11 is two, and the two cup bodies 11 are symmetrically arranged at two sides of the bra main body 10. The cup body 11 comprises an inner layer 110 and an outer layer 112, and the inner layer 110 is attached to the outer layer 112. When the intelligent bra is worn, the inner layer 110 is in contact with the skin of a human body, and the outer layer 112 faces away from the skin of the human body. The vibration module 20 and the heating module 30 are respectively disposed between the inner layer 110 and the outer layer 112.

The lower digging belt 12 is respectively connected to the lower sides of the two cup bodies 11, and the two cup bodies 11 are respectively arranged on the front side of the lower digging belt 12. The lower scrabbling belt 12 is in a belt shape, the back of the lower scrabbling belt 12 is provided with a row of separable buckles, and the buckles can form a ring shape after being hooked and connected, so that a user can wear the belt conveniently. Wherein, the front of taking off the area 12 down is the one side towards human chest when dressing, the back of taking off the area 12 down is the one side towards human back when dressing, the upside of cup 11 is the one side that deviates from ground when dressing, the downside of cup 11 is the one side towards ground when dressing.

The number of the shoulder straps 13 is two, one end of each shoulder strap 13 is connected to the upper side of the cup body 11, and the other ends of the two shoulder straps 13 are respectively connected to the lower scrabbling belt 12. The shoulder straps 13 are intended to be secured to the shoulders of a person when worn. It will be appreciated that in some embodiments, shoulder straps 13 may also be omitted.

Referring to fig. 3 to 5, the vibration module 20 includes a first vibration module 21 and a second vibration module 22 which are arranged at an interval, and the first vibration module 21 is disposed on the upper side of the second vibration module 22. The first vibration module 21 comprises a plurality of first vibration motors 210, the first vibration motors 210 are arranged at intervals, and the first vibration motors 210 are distributed in a U shape according to human engineering. The second vibration module 21 includes a plurality of second vibration motors 220, the plurality of second vibration motors 220 are arranged at intervals, and the plurality of second vibration motors 210 are distributed in a U-shape according to human engineering. The first vibration module 21 and the second vibration module 22 are respectively arranged between the inner layer 110 and the outer layer 112 of the cup body 11, and the first vibration motor 210 and the second vibration motor 220 respectively perform reciprocating motion through output shafts thereof to generate vibration for massaging. In this embodiment, the first vibration motor 210 and the second vibration motor 220 are Z-axis motors, respectively, and the Z-axis motors are configured to vibrate by reciprocating an output shaft along their own axes. In some other embodiments, the first vibration motor 210 and the second vibration motor 220 may also be an eccentric wheel vibration motor, a button motor, a micro electric hammer, or the like. It will be appreciated that in some embodiments, one of the first and second seismic modules 21, 22 may also be omitted.

In this embodiment, the number of the first vibration modules 21 and the number of the second vibration modules 22 are two, and each cup 11 is provided with a corresponding one of the first vibration modules 21 and a corresponding one of the second vibration modules 22.

Further, two U-shaped mounting grooves 114 are formed in the cup body 11, and the vibration module 20 is mounted in the mounting grooves 114. The surface of the outer layer 112 facing the inner layer 110 may be provided with a U-shaped groove to form the mounting groove, or the surface of the inner layer 110 facing the outer layer 112 may be provided with a U-shaped groove to form the mounting groove, or the surfaces of the inner layer 110 and the outer layer 112 opposite to each other are respectively provided with U-shaped grooves having the same shape, and the U-shaped groove on the inner layer 110 and the U-shaped groove on the outer layer 112 are spliced to form the mounting groove, which is not limited herein. In this embodiment, the mounting groove 114 is formed on a surface of the outer layer 112 facing the inner layer 110. Specifically, the two mounting grooves 114 include a first mounting groove 114a and a second mounting groove 114b, the first vibration module 21 is disposed in the first mounting groove 114a, and the second vibration module 22 is disposed in the second mounting groove 114 b. Two be equipped with soft silica gel respectively in the mounting groove 114 and fill to it is right first shock dynamo 210 with second shock dynamo 220 carries out waterproofly, and avoids first shock dynamo 210 with second shock dynamo 220 rubs user's skin.

Referring to fig. 6, the heating module 30 includes a heating plate 31, and the heating plate 31 is fixed in the cup body 11 by gluing. The heating plate 31 is U-shaped, and the heating plate 31 is arranged between the first vibration module 21 and the second vibration module 22. The heating sheet 31 generates heat to promote blood circulation and lymph circulation. In this embodiment, the number of the heating sheets 31 is two, and one heating sheet 31 is provided for each cup body 11.

The sensing module 40 includes a Micro Electro Mechanical Systems (MEMS) sensor 41 and a piezoelectric film sensor 42, and the MEMS sensor 41 is electrically connected to the piezoelectric film sensor 42. The micro-electromechanical sensor 41 and the piezoelectric film sensor 42 are used for collecting physiological signals of a user and transmitting the physiological signals to the control module 50.

The micro-electro-mechanical sensor 41 and the piezoelectric film sensor 42 are respectively installed on the lower scrabbling belt 12, so that discomfort caused when the micro-electro-mechanical sensor 41 and the piezoelectric film sensor 42 are in contact with the skin is avoided, and meanwhile, in order to facilitate water washing, the micro-electro-mechanical sensor 41 and the piezoelectric film sensor 42 are respectively packaged by flexible materials which are skin-friendly and washable, for example, the micro-electro-mechanical sensor 41 and the piezoelectric film sensor 42 can be packaged by adopting nano antibacterial waterproof materials.

The micro-electromechanical sensor 41 is arranged in the middle of the front face of the lower scrabbling belt 12, the micro-electromechanical sensor 41 is positioned between the two cup bodies 11, and the micro-electromechanical sensor 41 is close to the heart and used for collecting physiological signals of a user. The micro-electro-mechanical sensor is integrated with a BCG (Ballistocardiogram) acquisition module, and the BCG acquisition module does not need to contact the body of a user when acquiring signals, so that discomfort of the user can be avoided. The hardware scheme of the BCG acquisition module can adopt a piezoelectric film sensor and an array thereof, an acceleration sensor and an array thereof, a gyroscope and an array thereof or an optical fiber sensor and an array thereof and the like which can be used for acquiring a micro-motion signal.

The number of the piezoelectric film sensors 42 is two, the two piezoelectric film sensors 42 are respectively arranged on two sides of the micro electromechanical sensor 41, and each piezoelectric film sensor 42 extends from the micro electromechanical sensor 41 to the row buckle on the back of the lower scrabbling belt 12. The piezoelectric film sensor 42 is a sensor made of a novel polymer piezoelectric material, namely polyvinylidene fluoride, and is high in sensing sensitivity and capable of converting weak mechanical vibration signals into corresponding electrical signals. The pressure generated by the heartbeat of the human body and the respiration of the human body relative to the piezoelectric film sensor 42 can be converted into corresponding electric signals through the piezoelectric film sensor 42, so that the physiological signals of the user can be acquired.

In this embodiment, the physiological signal includes a respiration signal and a heart rate signal, the micro-electromechanical sensor 41 is used for acquiring the heart rate signal of the user, and the piezoelectric film sensor 42 is used for acquiring the respiration signal of the user. The two piezoelectric film sensors are used for detecting respiratory signals of a user, the two respiratory signals are input into the controller to calculate the respiratory rate, and the controller algorithm module can adopt various methods to reduce noise (filters, wavelet transformation, ICA and empirical mode decomposition-EMD), eliminate motion interference and obtain respiratory signals with good quality. Because two paths of piezoelectric film sensors are adopted to detect the breathing signals of the user, a blind source separation algorithm can be adopted based on the prior art, and the purpose of effectively eliminating noise is achieved. It is understood that in some embodiments, the micro-electromechanical sensor 41 may also be used to collect the respiration signal of the user, and the piezoelectric film sensor 42 may also be used to collect the heart rate signal of the user. Will the collection of heart rate signal with the collection of respiration signal is respectively carried out with two kinds of sensors, based on prior art, can separate target signal and noise better. It will be appreciated that in some embodiments, the physiological signal also includes a body temperature signal, a sweat signal, an electroencephalogram signal, and the like.

The sensing module 40 further includes a temperature sensor (not shown) mounted to the heating sheet 31. The temperature sensor is configured to collect temperature information of the heating sheet 31 and transmit the temperature information to the control module 50.

Referring to fig. 6 to 8, the control module 50 is disposed on the lower scrabbling belt 12, and includes a main control unit 51 and a storage unit 52, and the storage unit 52 is electrically connected to the main control unit 51.

The main control unit 51 is electrically connected with the sensing module 40, and the main control unit 51 is used for receiving the physiological signals collected by the sensing module 40, processing and analyzing the physiological signals, and calculating physiological data such as heart rate, respiration, HRV, mental stress index and the like. Specifically, the main control unit 51 receives a respiration signal or a heart rate signal sent by the micro electro mechanical sensor 41 or the piezoelectric film sensor 42, and processes the respiration signal or the heart rate signal according to a preset condition to obtain effective physiological data, where the effective physiological data includes heart rate data, respiration data, heart rate variability data or a mental pressure variation curve meeting the preset condition, that is, target heart rate data, target respiration data, and heart rate variability data or a mental pressure variation curve calculated according to the target heart rate data and the target respiration data. The main control unit 51 includes an algorithm module, and the algorithm module may perform noise reduction by using one or a combination of multiple methods including a filter, wavelet transformation, independent component analysis, empirical mode decomposition, and the like, and eliminate an interference signal in an acquisition process to obtain the respiratory signal or the heart rate signal with better quality. The storage unit 52 is configured to store effective physiological data processed by the main control unit 51, where the effective physiological data includes heart rate data, respiration data, heart rate variability data, or a mental pressure variation curve that meets preset conditions. In some embodiments, the storage unit 52 includes a prompting unit, and the prompting unit is configured to prompt the user to upload the valid physiological data in time when the storage space occupation of the storage unit 52 exceeds a preset ratio.

The main control unit 51 is further electrically connected to the vibration module 20 and the heating module 30, and the main control unit 51 can control the vibration module 20 and the heating module 30 to be turned on or off. The main control unit 51 is respectively connected with the first vibration motors 210 and the second vibration motors 220 through the motor driving circuit, and the main control unit 51 can respectively control each of the first vibration motors 210 and the second vibration motors 220 to be opened or closed, so that different vibration effects are formed. The main control unit 51 is further electrically connected to the heating sheet 31 through a heating driving circuit, and the main control unit 51 may control the heating sheet 31 to be turned on or turned off. After the heating plate 31 is opened, the main control unit 51 can measure the temperature of the heating plate 31 in real time through the temperature sensor, and then accurately control the temperature of the heating plate 31 according to different functions and requirements.

The master control unit 51 acts as a controller and may be a general purpose processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA), a single chip, an arm (acorn RISC machine) or other programmable logic device, discrete gate or transistor logic, discrete hardware components, or any combination of these components. For example, the MCU may be of the STM32F103 type, or the like, and the controller may be any conventional processor, controller, microcontroller, or state machine. A controller may also be implemented as a combination of computing devices, e.g., a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core, or any other such configuration.

In some embodiments, the control module 50 further includes a communication unit 53, and the communication unit 53 is electrically connected to the storage unit 52 and is used for establishing a communication connection between the storage unit 52 and an external electronic device. The communication unit 53 transmits the valid physiological data stored in the storage unit 52 to an external electronic device to form a health report for the user. The communication unit 53 is further electrically connected to the main control unit 51, and the communication unit 53 may receive a program instruction sent by an external electronic device and transmit the program instruction to the main control unit 51, so that the external electronic device may control the vibration module 20 and the heating module 30 through the main control unit 51. The communication unit 53 may be a Wi-Fi communication module, a bluetooth module, a General Packet Radio Service (GPRS) communication module, an infrared module, a Global system for mobile communication (GS) communication module, or the like.

In some embodiments, the control module 50 further includes a button (not shown) electrically connected to the main control unit 51, and a user can control the operation of the vibration module 20 and the heating module 30 through the button. Specifically, each of the vibration modules 20 includes a first vibration motor 210 and a second vibration motor 220, which are capable of outputting different vibration effects independently, and different vibrations are continuously combined to form a set of complete vibration operation, and different vibration operations are different in effect modes, such as a massage mode, a pressure reduction mode, a reminding mode, and the like. The user may select different effect modes through an operation key, and the main control unit 51 controls each of the first vibration motors 210 and each of the second vibration motors 220 to independently operate according to the effect mode selected by the user, thereby performing different vibration operations. The user can also select to turn on or off the heating module 30 and adjust the heating temperature of the heating module 30 by operating keys, and the main control unit 51 controls the heating sheet 31 to perform heating according to the selection of the customer.

Further, a control box 14 is arranged on one side of the lower stripping belt 12, the control box 14 is adhered to the lower stripping belt 12, and the control module 50 is arranged in the control box 14. In this embodiment, the main control unit 51, the storage unit 52 and the communication unit 53 of the control module 50 are respectively integrated on a circuit board, and the circuit board can be fixed to the control box 14 by screwing, bonding, welding, etc. After the control module 50 is installed in the control box 14, a glue filling manner may be adopted for performing a waterproof process.

The power supply module 60 comprises a power supply 61 and a lead 62, and the power supply 61 is connected with the lead 62. The power source 61 is arranged on the lower digging belt 12, and the lead 62 extends from the lower digging belt 12 to the cup body 11. The power source 61 may be a dry battery, a rechargeable battery, a wireless charging module, or the like.

The wires 62 are respectively connected to the first vibration motors 210, the second vibration motors 220, the heating sheet 31, the micro-electromechanical sensor 41, the piezoelectric film sensor 42 and the main control unit 51, so as to electrically connect the vibration module 20, the heating module 30, the sensing module 40, the control module 50 and the power supply module 60. The main control unit 51 may control the power source 61 to be turned on, so that the power source 61 respectively supplies power to the control module 50, the vibration module 20, the heating module 30, and the sensing module 40. In this embodiment, the user may select to turn on or off the power supply 61 by operating a key, or the user may control the power supply 61 to turn on or off by a program instruction of an external electronic device. The lead 62 is fixed to the bra main body 10 by bonding, and the part of the lead 62 connecting the vibration module 20 and the heating module 30 is arranged in the mounting groove of the cup body 11 and is subjected to waterproof treatment by soft silica gel; the part of the lead 62 connecting the sensing module 40 and the control module 50 is arranged along the upper side edge of the lower scrabbling belt 12 and is encapsulated by a waterproof material.

Further, a power supply box 15 is arranged on one side of the lower scrabbling belt 12, and the power supply 61 is arranged in the power supply box 15. In this embodiment, the power source 61 is fixed to the lower pulling-off strap 12 through a snap fastener, the power box 15 is adhered to the lower pulling-off strap 12, and the power source 61 can be fixed and waterproofed in the power box 15 by means of glue filling. It will be appreciated that in some other embodiments, the power source 61 may be secured to the lower gin pole 12 by screwing, gluing, etc. The power supply box 15 is further provided with wire outlet holes, and the wires 62 can pass through the wire outlet holes to be connected with the modules.

In some embodiments, the power supply module 60 further includes a power switch (not shown) disposed at the buckle of the lower clamp strap 12, and the power switch is electrically connected to the piezoelectric film sensor 42. When the user dresses when intelligent brassiere, the row is buckled so that power 61 opens, when the user takes off when intelligent brassiere, the row is buckled the separation so that power 61 self-closing stops the power supply.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; within the idea of the utility model, also technical features in the above embodiments or in different embodiments may be combined, steps may be implemented in any order, and there are many other variations of the different aspects of the utility model as described above, which are not provided in detail for the sake of brevity; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. An intelligent bra, comprising:

a bra body;

the vibration module is arranged on the bra body;

the heating module is arranged on the bra body;

the sensing module is arranged on the bra body and is used for acquiring physiological signals of a user;

the control module is arranged on the bra body, is respectively connected with the vibration module, the heating module and the sensing module, and is used for receiving and processing physiological signals acquired by the sensing module and respectively controlling the vibration module and the heating module to work;

the power supply module is arranged on the bra body and connected with the control module, and the power supply module is used for supplying power to the vibration module, the heating module, the sensing module and the control module respectively.

2. The smart bra of claim 1, wherein the vibrator module comprises a first vibrator module comprising a plurality of first vibrator motors arranged in a spaced apart arrangement.

3. The smart bra of claim 2, wherein the vibration module further comprises a second vibration module spaced apart from the first vibration module;

the second vibration module comprises a plurality of second vibration motors which are arranged at intervals.

4. The smart bra of claim 3, wherein the plurality of first vibratory motors are spaced apart in a U-shape; and/or

The plurality of second vibrating motors are arranged at intervals in a U shape.

5. The smart bra of any one of claims 3-4, wherein the heating device comprises a heat patch disposed between the first vibratory module and the second vibratory module.

6. The smart bra of claim 1, wherein the bra body comprises a lower scrabbling belt and two cup bodies, the two cup bodies being connected to the lower scrabbling belt, respectively;

the vibration module and the heating module are respectively arranged on the two cup bodies, and the sensing module, the control module and the power supply module are respectively arranged on the lower scrabbling belt.

7. The smart bra of claim 6, wherein the sensing module comprises a micro-electromechanical sensor and a piezoelectric film sensor, the micro-electromechanical sensor electrically coupled to the piezoelectric film sensor,

the micro-electromechanical sensor is arranged on the front surface of the lower scrabbling belt and is positioned between the two cup bodies;

the piezoelectric film sensor extends from the micro-electromechanical sensor to the back of the lower scrabbling belt;

the micro-electromechanical sensor and the piezoelectric film sensor are respectively used for acquiring physiological signals of a user, and the physiological signals comprise heart rate signals and respiration signals.

8. The intelligent bra of claim 7, wherein the control module is disposed on the lower scrabbling belt, the control module comprising a master control unit, a storage unit, and a communication unit;

the main control unit is respectively connected with the micro-electromechanical sensor and the piezoelectric film sensor and is used for processing and analyzing physiological signals collected by the micro-electromechanical sensor and the piezoelectric film sensor and calculating effective physiological data;

the storage unit is used for storing the effective physiological data processed by the main control unit

The communication module is used for transmitting the effective physiological data stored in the storage unit to the external electronic equipment.

9. The intelligent bra of claim 8, wherein the lower scrabbling belt is provided with a control box, and the control module is provided in the control box.

10. The smart bra of any one of claims 8-9, wherein the power module comprises a power source, the power source being coupled to the master control unit;

the lower scrabbling belt is provided with a power supply box, and the power supply is arranged in the power supply box.

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