SUMMERY OF THE UTILITY MODEL
One aspect of the present disclosure provides a temperature measurement patch. The temperature measurement patch can comprise a first information processing module, a temperature measurement module, a human body induction module, a first information transmission module, a power supply module and a protection module.
The temperature measuring module, the human body induction module and the first information transmission module are connected with the first information processing module. The power supply module is respectively connected with the first information processing module, the temperature measuring module, the human body induction module and the first information transmission module through a timing switch.
The first information processing module, the temperature measuring module, the human body induction module, the first information transmission module, the power supply module and the timing switch are hermetically arranged in the protection module at intervals, so that blank grooves are formed among the first information processing module, the temperature measuring module, the human body induction module, the first information transmission module, the power supply module and the timing switch.
Through setting up above-mentioned temperature measurement paster on clothing or other wearable article, each module is regularly opened in the temperature measurement paster, can regularly accomplish the temperature measurement to human body. And data can be transmitted to a computer, a smart phone or a tablet personal computer and other terminals through the first information processing module, so that a user can conveniently check and record the data, an abnormal prompt can be set through the computer, the smart phone or the tablet personal computer and other terminals, and an alarm prompt is given when the overhigh or overlow body temperature is detected. In addition, the power supply is controlled by adopting the timing switch, the power supply is turned on and maintains a constant running state in a certain period range, and then the power supply is turned off, so that the standby power consumption of a subsequent circuit is eliminated, and the excellent effect of saving electric energy is embodied; and the period of the timing switch can be dynamically adjusted, when the user wears the temperature measurement patch, the period of the timing switch is shortened, and if the user does not wear the temperature measurement patch, the period is lengthened, so that the energy loss in the transportation and storage processes is reduced. In addition, by arranging the blank groove, the temperature measurement patch can be protected while providing a mounting space for a connecting line between the electronic modules, and the temperature measurement patch can be buffered by adverse factors such as external folding, deformation and distortion; and the blank groove can also play a role in heat dissipation, and the operation performance of the element is guaranteed.
According to some preferred embodiments of the present disclosure, the protective module includes a first protective layer and a second protective layer. The first protective layer and the second protective layer are arranged oppositely and sealed at the periphery, so that a sealed cavity is formed between the first protective layer and the second protective layer. The first information processing module, the temperature measuring module, the human body induction module, the first information transmission module, the power supply module and the timing switch are arranged in the sealing cavity in a sealing mode at intervals.
According to some preferred embodiments of the present disclosure, the protective module includes a first protective layer, a second protective layer, a third protective layer, and a fourth protective layer. The first protective layer and the second protective layer are oppositely arranged; the third protective layer and the fourth protective layer are oppositely arranged between the first protective layer and the second protective layer and are sealed at the periphery; so that a sealed cavity is formed between the third protective layer and the fourth protective layer. The first information processing module, the temperature measuring module, the human body induction module, the first information transmission module, the power supply module and the timing switch are arranged in the sealing cavity in a sealing mode at intervals.
According to some preferred embodiments of the present disclosure, the first protective layer and the second protective layer are TPU composite layers.
According to some preferred embodiments of the present disclosure, the third protective layer and the fourth protective layer are EVA material layers.
According to some preferred embodiments of the present disclosure, the first information processing module is an MCU. The temperature measuring module is a temperature sensor. The human body induction module is a human body induction chip or a human body induction sensor. The first information transmission module comprises a low-power Bluetooth module and/or a sub1G module. The power supply module comprises a storage battery, a solar panel and/or a temperature difference power generation device.
Another aspect of the present disclosure provides a temperature measurement system. The temperature measurement system comprises a temperature measurement patch as described in any one of the above and a user terminal. The temperature measurement patch is in communication connection with the user terminal.
According to some preferred embodiments of the present disclosure, the user terminal is a computer, a smartphone, or a tablet computer. Or the user terminal comprises a second information processing module, a second information transmission module and a display module, wherein the second information transmission module can be in communication connection with the first information transmission module; the second information transmission module and the display module are respectively connected with the second information processing module.
Yet another aspect of the present disclosure provides a wearable article. The wearable article comprises a wearable article body and a temperature measurement patch as described in any of the above. The temperature measurement patch is arranged on the wearable article body.
According to some preferred embodiments of the present disclosure, the wearable article body is a garment, a quilt, a pad, a scarf, a glove, a protector, or a wearable electronic device.
This is disclosed through setting up above-mentioned temperature measurement paster on clothing or other wearable article, and each module is regularly opened in the temperature measurement paster, can regularly accomplish the body temperature measurement to the human body. And data can be transmitted to a computer, a smart phone or a tablet personal computer and other terminals through the first information processing module, so that a user can conveniently check and record the data, an abnormal prompt can be set through the computer, the smart phone or the tablet personal computer and other terminals, and an alarm prompt is given when the overhigh or overlow body temperature is detected. In addition, the power supply is controlled by adopting the timing switch, the power supply is turned on and maintains a constant running state in a certain period range, and then the power supply is turned off, so that the standby power consumption of a subsequent circuit is eliminated, and the excellent effect of saving electric energy is embodied; and the period of the timing switch can be dynamically adjusted, when the user wears the temperature measurement patch, the period of the timing switch is shortened, and if the user does not wear the temperature measurement patch, the period is lengthened, so that the energy loss in the transportation and storage processes is reduced. In addition, by arranging the blank groove, the temperature measurement patch can be protected while providing a mounting space for a connecting line between the electronic modules, and the temperature measurement patch can be buffered by adverse factors such as external folding, deformation and distortion; and the blank groove can also play a role in heat dissipation, and the operation performance of the element is guaranteed.
Additional features of some aspects of the disclosure may be set forth in the description which follows. Additional features of some aspects of the disclosure will be apparent to those skilled in the art upon examination of the following description and accompanying drawings or may be learned by the manufacture or operation of the embodiments. The features of the present disclosure may be realized and attained by practice or use of various methods, instrumentalities and combinations of the specific embodiments described below.
Detailed Description
In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.
On the contrary, this application is intended to cover any alternatives, modifications, equivalents, and alternatives that may be included within the spirit and scope of the application as defined by the appended claims. Furthermore, in the following detailed description of the present application, certain specific details are set forth in order to provide a better understanding of the present application. It will be apparent to one skilled in the art that the present application may be practiced without these specific details.
In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings used in the description of the embodiments will be briefly introduced below. It is obvious that the drawings in the following description are only examples or embodiments of the application, from which the application can also be applied to other similar scenarios without inventive effort for a person skilled in the art. It is understood that these exemplary embodiments are given solely to enable those skilled in the relevant art to better understand and implement the present application, and are not intended to limit the scope of the present application in any way. Unless otherwise apparent from the context, or otherwise indicated, like reference numbers in the figures refer to the same structure or operation.
As used in this application and the appended claims, the terms "a," "an," "the," and/or "the" are not intended to be inclusive in the singular, but rather are intended to be inclusive in the plural unless the context clearly dictates otherwise. In general, the terms "comprises" and "comprising" merely indicate that steps and elements are included which are explicitly identified, that the steps and elements do not form an exclusive list, and that a method or apparatus may include other steps or elements. The term "based on" is "based, at least in part, on". The term "one embodiment" means "at least one embodiment"; the term "another embodiment" means "at least one additional embodiment". "plurality" means two or more. "at least one" means one or more than one. "first," "second," … …, and the like are used for distinguishing between similar elements and not necessarily for describing a sequential or chronological order.
One aspect of the present disclosure provides a temperature measurement patch. The temperature measuring patch may include a first information processing module 100, a temperature measuring module 200, a human body sensing module 300, a first information transmitting module 400, a power supply module 500, a time switch 600, and a protection module 700. The temperature measuring module 200, the human body sensing module 300, and the first information transmitting module 400 are connected to the first information processing module 100. The power supply module 500 is connected to the first information processing module 100, the temperature measuring module 200, the human body sensing module 300, and the first information transmission module 400 through a time switch 600. The first information processing module 100, the temperature measuring module 200, the human body induction module 300, the first information transmission module 400, the power supply module 500, and the timer switch 600 are hermetically disposed in the protection module 100 in a spaced manner, so that a blank groove 760 is formed between the first information processing module 100, the temperature measuring module 200, the human body induction module 300, the first information transmission module 400, the power supply module 500, and the timer switch 600, as shown in fig. 1, 2, and 3.
Through setting up above-mentioned temperature measurement paster on clothing or other wearable article, each module is regularly opened in the temperature measurement paster, can regularly accomplish the temperature measurement to human body. And data can be transmitted to a terminal such as a computer, a smart phone or a tablet computer through the first information processing module 100, so that a user can conveniently check and record the data, an abnormal prompt can be set through the terminal such as the computer, the smart phone or the tablet computer, and an alarm prompt is given when the overhigh or overlow body temperature is detected. In addition, the power supply is controlled by adopting the timing switch, the power supply is turned on and maintains a constant running state in a certain period range, and then the power supply is turned off, so that the standby power consumption of a subsequent circuit is eliminated, and the excellent effect of saving electric energy is embodied; in addition, by arranging the blank groove 760, the temperature measurement patch can be protected while providing a mounting space for a connecting line between the electronic modules, and the temperature measurement patch can be buffered by adverse factors such as external folding, deformation and distortion; and the blank groove 760 can also play a role in heat dissipation, so that the operation performance of the element is guaranteed.
Further, since the patch is disposed on a wearing article, such as a garment, it is a measurement mode for the temperature of the garment: namely, the temperature of the clothes is directly measured by using the patch. Its advantage lies in that the temperature measurement paster directly contacts with clothes itself, and its contact form is: on one hand, the patch can be attached to the surface of clothes, on the other hand, the patch can be embedded into an interlayer of the clothes, and the measured data is more accurate; in addition, the patch has strong temperature stability, the measurement result is not deviated due to the influence of fluctuating external environment, and the error range of the measured temperature can be ensured to be between 0.1 ℃ and 5 ℃. Particularly, the measurable temperature range of the patch is between 0 ℃ and 100 ℃, and the patch can accurately measure the temperature of clothes from a specified range section
In some embodiments, the first information processing module 100 may employ a Microcontroller (MCU). In order to reduce the thickness of the temperature measurement patch, the MCU can be selected to have a small size and extremely low power consumption. For example, Texas Instruments, Inc. cc1310, cc2640, Nordic, Inc. NRF51822, NRF51810, NRF51820, Atmel, Inc. ATtiny 102/104, Feichka's ultrathin version of the Kinetis K22 microcontroller, or Feichka's also Cortex-M0+ core Kinetis KL03MCU, etc.
The first information processing module 100 may adjust the switching period of the time switch 600 according to whether the temperature measurement patch is in a worn state.
For example, the flow of the first information processing module 100 adjusting the switching period of the time switch 600 may be as shown in fig. 5.
Wherein, the Bayesian network algorithm can be adopted for judging whether the temperature measuring patch is in the worn state. The specific method comprises the following steps:
first, the physical wearing procedure of the temperature measurement patch is modeled, as shown in the bayesian network of fig. 6: the state at the previous moment and the state at the current moment influence the temperature value and the temperature difference value of the current state, and the response value of the human body induction at the current moment is only influenced by the state at the current moment.
Wherein S represents a state at a current moment, Sp represents a state at a previous moment, S ═ 1 represents a wearing state, S ═ 0 represents a non-wearing state, T represents a temperature value at the current moment, dT represents a temperature difference between the current moment and the previous moment, and C represents a measurement value of human body induction at the current moment; a probabilistic model expression can thus be obtained:
P(S=1)=P(T,dT|Sp,S=1)x 1(C|S=1);
P(S=0)=P(T,dT|Sp,S=0)x P(C|S=0);
if P (S ═ 1) > P (S ═ 0), the current state is the worn state, otherwise, the unworn state.
Real sample data is obtained by utilizing an experiment; and estimates P (Tn, dTn | Sn-1, Sn) and P (Cn | Sn); wherein Tval represents the value of the temperature value T at the current moment, and dTval represents the values of the current moment and the last momentTemperature difference, ymRepresents the state value, y, of the last state SpkAnd the state value of the state S at the current moment is represented, i represents the ith sample, and Cval represents the value of the human body induction sensor C at the current moment.
By adopting the Bayesian network, the current state of the temperature measurement patch is judged, the calculated amount in data processing is reduced, and the judgment is more accurate.
In these embodiments, by dynamically adjusting the period of the time switch, the time switch period is shorter when the user wears the temperature measurement patch, and the period is longer if the user does not wear the temperature measurement patch, to reduce energy loss during transportation and storage.
In some embodiments, the temperature measurement module 200 may employ a temperature sensor. For example, a sheet-type temperature sensor may be employed. In some embodiments, the temperature measurement module 200 may also employ temperature acquisition circuitry.
In some embodiments, the human body sensing module 300 may employ a human body sensing chip. For example, a TC301D type human body sensing chip may be used. In some embodiments, the human body sensing module 300 may also employ a human body sensing sensor that can sense a human body. Such as an Acconeer PCR radar sensor.
In some embodiments, the first information transmission module 400 may employ bluetooth low energy. Bluetooth transmission is the lower wireless transmission mode of a consumption, and bluetooth wireless transmitter can reduce the temperature measurement paster consumption, guarantees to use longer time. In some embodiments, the sub1G module may also be adopted as the first information transmission module 400. Such as a sub1G chip. The Sub-1G frequency band is the application-free section transmitting and receiving frequency of our country, can be directly used, has strong penetrability and is suitable for the application with more barriers and needing wireless transmission. The Sub-1G can be further divided into four frequency band series of 430-440MHz, 450-470 MHz, 868-870 MHz and 902-928MHz according to the wireless transmission frequency band. Compared with the 2.4G frequency band, the Sub-1G frequency band has better coverage effect and capacity effect, and is widely applied to the fields of mobile communication and wireless networks at present. In some embodiments, the first information transmission module 400 may also adopt a combination of various wireless transmission modes. For example, a combination of a bluetooth wireless transmitter and a sub1G module is employed.
The signal transmitting device with the low-power-consumption Bluetooth module and the sub1G module as the temperature measuring patches can transmit signals in an efficient and energy-saving mode, and a user can monitor the temperature change condition in real time through a temperature display terminal, such as a computer, a smart phone or a tablet computer (e.g., APP, small programs and the like).
In some embodiments, the power supply module 500 may employ a battery. Illustratively, a micro battery may be employed. Such as micro thin film batteries, micro button batteries, etc. In some embodiments, the power module 500 may also employ a solar panel, such that the temperature measurement patch may be charged and/or powered in light. For example, articles such as clothes, quilts, pads, scarves, gloves, and protectors provided with the temperature measurement patch can be charged and/or powered when hung or used under light. In some embodiments, thermoelectric generation techniques may be applied to the module that obtains electrical energy, and power generation may be performed using thermoelectric generation techniques by comparing the temperature difference relationship between the ambient temperature and the temperature of the clothing. That is, the power supply module 500 may employ a thermoelectric generation device. In some embodiments, the power module 500 may also employ any combination of batteries, solar panels, and thermoelectric generation devices.
In some embodiments, the timing switch 600 may employ a timing switch circuit. The power supply is controlled by the timing switch, the power supply is turned on and maintained in a constant running state within a certain period range, and then the power supply is turned off, so that the standby power consumption of a subsequent circuit is eliminated, and the excellent effect of saving electric energy is embodied.
In some embodiments, the protection module 700 may include a first protection layer 710 and a second protection layer 720. The first protective layer 710 and the second protective layer 720 are disposed opposite to each other and sealed at their peripheries, such that a sealed cavity 750 is formed between the first protective layer 710 and the second protective layer 720. For example, the first protection layer 710 and the second protection layer 720 may be disposed in parallel and spaced up and down, and the peripheries of the first protection layer 710 and the second protection layer 720 are sealed and connected by a sealing strip in an adhesive manner, so that a sealed cavity 750 is formed between the first protection layer 710 and the second protection layer 720. For example, the first protection layer 710 and the second protection layer 720 may be integrally formed by injection molding or the like, and a sealed cavity 750 is formed between the first protection layer 710 and the second protection layer 720.
In some embodiments, the protection module 700 includes a first protection layer 710, a second protection layer 720, a third protection layer 730, and a fourth protection layer 740. The first protective layer 710 and the second protective layer 720 are disposed opposite to each other. The third protective layer 730 and the fourth protective layer 740 are oppositely arranged between the first protective layer 710 and the second protective layer 720 and are sealed at the periphery; so that a sealed cavity 750 is formed between the third protective layer 730 and the fourth protective layer 740. Specifically, the lower surface of the first protection layer 710 and the upper surface of the third protection layer 730 can be hermetically connected together by bonding or integral molding. The upper surface of the second protective layer 720 and the lower surface of the fourth protective layer 740 can be hermetically connected together by bonding or integral molding. The third protective layer 730 and the fourth protective layer 740 are arranged in parallel up and down at intervals, and the peripheries of the third protective layer 730 and the fourth protective layer 740 are hermetically connected in a bonding mode through sealing strips, so that a sealed cavity 750 is formed between the third protective layer 730 and the fourth protective layer 740.
The first information processing module 100, the temperature measuring module 200, the human body sensing module 300, the first information transmission module 400, the power supply module 500 and the time switch 600 are hermetically disposed in the sealed cavity 750 in a spaced manner, as shown in fig. 1, 2 and 3. So that a blank groove 760 is formed between the first information processing module 100, the temperature measuring module 200, the human body sensing module 300, the first information transmitting module 400, the power supplying module 500 and the time switch 600.
A blank groove 760 is formed among the first information processing module 100, the temperature measuring module 200, the human body sensing module 300, the first information transmitting module 400, the power supply module 500 and the time switch 600, so that a mounting space can be provided for a connection line between the respective modules; on the other hand, the blank groove can protect the patch, and can play a certain buffering role on the patch due to external adverse factors such as folding, deformation and distortion; meanwhile, the middle part is provided with a hollow groove for heat dissipation, so that the operation performance of the element is guaranteed.
In some embodiments, the first protective layer 710 and the second protective layer 720 are TPU composite layers.
The TPU composite material layer is formed by bonding and adhering a layer of textile material and other functional materials. The compounded fabric has the special functions of softness, water resistance, moisture permeability, radiation resistance, washing resistance, abrasion resistance and the like. TPU (thermoplastic polyurethanes), thermoplastic polyurethanes, are linear block copolymers composed of soft segments of oligomeric polyols and hard segments of diisocyanate-chain extenders. The TPU can be made into a film by casting, film blowing, rolling or coating, and has the advantages of good elasticity, toughness, wear resistance, good cold resistance, environmental protection, no toxicity and the like. Inside whole circuit entity components and parts will be made up in textile goods, two-layer is wrapped up by the TPU material about whole, has realized waterproof function, and whole temperature measurement paster accessible TPU is made up on the cloth simultaneously.
In some embodiments, the third protective layer 730 and the fourth protective layer 740 are EVA material layers.
EVA is copolymerized by ethylene and acetic acid, and has the Chinese cultural name: ethylene-vinyl acetate copolymer (ethylene-vinyl acetate copolymer), chemical name in english: ethylene Vinyl Acetate Copolymer. The EVA has wide application field, and the EVA product is a novel environment-friendly plastic foaming material, has the advantages of good buffering, shock resistance, heat insulation, moisture resistance, chemical corrosion resistance and the like, and is non-toxic and non-absorbent. Guarantee under the prerequisite that realizes waterproof function and feel the comfort level, circuit arrangement all has the EVA to cover at upper and lower layers, utilizes the compliance of EVA, can improve the compliance of paster, can play the effect that prevents the electric leakage simultaneously.
In some embodiments, the elements of the temperature measurement patch are attached in a bi-directional manner. Illustratively, one element is affixed to each side of the EVA layer. For example, one side is pasted with a temperature measuring module, and the other side is pasted with a power supply module. The design advantages are as follows: firstly, the pressure of a single-side EVA layer is reduced, the adhesion strength of the elements is uniformly dispersed, the elements can be prevented from falling off and twisting deformation, and the elements on two sides can be uniformly stressed; secondly, the internal circuit conducting wire is convenient to extend, the conducting wire is prevented from being bent and folded, and the working performance of the element is ensured; thirdly, the heat dissipation is even, each element is pasted on the EVA layer at one side, and the EVA layer at each side can absorb the heat of the corresponding pasted element.
The warm clothes measuring patch can be made into a sheet structure with the thickness ranging from 0.01mm to 10mm and the length and width ranging from 0.1mm to 1000mm through the structure. When the clothes are stuck or sewn on the clothes, the wearing comfort can be improved. In addition, since all the electrical components in the patch are sealed in the protection module, the patch can be washed with the clothes.
Another aspect of the present disclosure relates to a temperature measurement system. The temperature measurement system includes a temperature measurement patch 10 as described in any of the above and a user terminal 20, as shown in fig. 4. Wherein the temperature measurement patch 10 is capable of communicative connection with the user terminal 20.
In some embodiments, the user terminal 20 is a computer, a smart phone, a smart band or a tablet computer. A computer, a smart phone, a tablet computer, or the like may be in communication with the first information transmission module 400, for example, the communication connection therebetween may be implemented by bluetooth.
In some embodiments, the user terminal 20 includes a second information processing module 21, a second information transmission module 22 capable of being communicatively connected with the first information transmission module 400, and a display module 23; the second information transmission module 22 and the display module 23 are respectively connected to the second information processing module 21. Through setting up above-mentioned temperature measurement paster on clothing or other wearable article, each module is regularly opened in the temperature measurement paster, can regularly accomplish the temperature measurement to human body. The temperature data collected by the temperature measurement patch can be transmitted to a user terminal such as a computer, a smart phone or a tablet personal computer through the first information processing module 100, so that the user can conveniently check and record the temperature data, an abnormal prompt can be set through the user terminal such as the computer, the smart phone or the tablet personal computer, and an alarm prompt is given when the overhigh or overlow body temperature is detected.
Yet another aspect of the present disclosure relates to a wearable article. The wearable article comprises a wearable article body 30 and a temperature measurement patch 10 as described in any of the above. The temperature measurement patch 10 is disposed on the wearable article body 30, as shown in fig. 7.
In some embodiments, the wearable article body 30 may be an article of clothing. For example, the clothing article in the present disclosure should be broadly understood to include articles such as hand (glove), foot (shoe, sandal, boot) and head (hat) shields, ornaments, and leather, in addition to the shields for the trunk and limbs.
In some embodiments, the wearable article body 30 may be a brace. Such as wristbands, knee pads, waist pads, and the like.
In some embodiments, the wearable article body 30 may be a wearable electronic device. Such as smart bands and the like.
In addition, the wearable article body 30 can also be a quilt, a protection pad, a scarf, a glove and other articles.
In some embodiments, the temperature measurement patch 10 may be removably disposed on the wearable article body 30. Exemplarily, the clothes can be arranged on the clothes in a detachable mode such as a magic tape and a non-setting adhesive, and the specific position can be selected according to actual needs without limitation. For example, the temperature-measuring patch 10 may be attached to the back collar, under the armpits, chest, left and right abdomens, and/or navel of a garment, etc.
In some embodiments, the temperature measurement patch 10 may be disposed on the wearable article body 30 in a fixed connection. Illustratively, the sewing can be carried out on a certain position of the clothes according to the requirement. For example, the temperature-measuring patch 10 may be sewn to the back collar of a garment, under the armpits, chest, left and right abdomens, and/or navel, etc.
The wearable article of the present disclosure is described in further detail below in connection with a specific embodiment.
As shown in fig. 7, a wearable article includes a wearable article body 30 and a temperature measurement patch 10.
Wherein the wearable article body 30 is a garment. The temperature measuring patch 10 is provided on the garment in a sewn manner.
Wherein, temperature measurement paster 10 includes first Microprocessor (MCU), temperature sensor, human body induction sensor, first bluetooth communication module, battery, time switch and protection module.
The temperature sensor, the human body induction sensor and the first Bluetooth communication module are respectively and electrically connected with a first Microprocessor (MCU).
The storage battery is respectively and electrically connected with the first Microprocessor (MCU), the temperature sensor, the human body induction sensor and the first Bluetooth communication module through the timing switch.
The protective module 700 comprises a first protective layer 710 and said second protective layer 720 made of a TPU composite material, and a third protective layer 730 and said fourth protective layer 740 made of an EVA material. The lower surface of the first protection layer 710 and the upper surface of the third protection layer 730 can be hermetically connected together by bonding or integral molding. The upper surface of the second protective layer 720 and the lower surface of the fourth protective layer 740 can be hermetically connected together by bonding or integral molding. The third protective layer 730 and the fourth protective layer 740 are arranged in parallel up and down at intervals, and the peripheries of the third protective layer 730 and the fourth protective layer 740 are hermetically connected in a bonding mode through sealing strips, so that a sealed cavity 750 is formed between the third protective layer 730 and the fourth protective layer 740.
First Microprocessor (MCU), temperature sensor, human body induction sensor, first bluetooth communication module, battery, time switch seal with the mode at mutual interval and set up in sealed chamber 750 to be formed with blank groove 760 between first Microprocessor (MCU), temperature sensor, human body induction sensor, first bluetooth communication module, battery, time switch.
Further, a user terminal 20 is included. The user terminal 20 includes a second Microprocessor (MCU), a second bluetooth communication module, and a display screen. Under the user state, first bluetooth communication module and second bluetooth communication module communication connection can transmit the temperature data that temperature measurement paster 10 gathered to user terminal 20, show the temperature value and according to the size of temperature data through the display screen display, report to the police and indicate.
In the above embodiments, each functional module/unit may be replaced with another module/unit having the same function. For example, the bluetooth communication module can be replaced by a sub1g module; the storage battery can be replaced by a solar panel or a temperature difference power generation device/module, or can be replaced by any combination of the storage battery, the solar panel and the temperature difference power generation device/module; the material of the protection module can be replaced by silicon gel and the like.
The beneficial effects that the embodiments of the present disclosure may bring include but are not limited to:
1. the protection module is formed by waterproof materials, so that the internal circuit is protected, and the temperature measurement patch can be washed by water;
2. various measures of low power consumption are adopted, so that the service life of the circuit can be prolonged;
3. whether the temperature measurement patch real object is worn or not is detected by adopting a Bayesian network algorithm, so that the judgment is more accurate;
4. a battery or a thermoelectric generation module is adopted as a power supply device, and no charging equipment is provided;
5. by adopting the wireless communication transceiver, data transmission can be directly carried out without external connection.
It should be noted that all of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except for mutually exclusive features and/or steps.
In addition, the above-described embodiments are exemplary, and those skilled in the art, having benefit of this disclosure, may devise various solutions that are within the scope of this disclosure and that fall within the scope of the disclosure. It should be understood by those skilled in the art that the present disclosure and its accompanying drawings are illustrative and not limiting to the claims. The scope of the disclosure is defined by the claims and their equivalents.