CN109662698A - Monitoring of pulse sensor, preparation method, pulse monitoring device and system - Google Patents
Monitoring of pulse sensor, preparation method, pulse monitoring device and system Download PDFInfo
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- CN109662698A CN109662698A CN201711338463.9A CN201711338463A CN109662698A CN 109662698 A CN109662698 A CN 109662698A CN 201711338463 A CN201711338463 A CN 201711338463A CN 109662698 A CN109662698 A CN 109662698A
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Classifications
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes
- A61B5/7203—Signal processing specially adapted for physiological signals or for diagnostic purposes for noise prevention, reduction or removal
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes
- A61B5/7225—Details of analog processing, e.g. isolation amplifier, gain or sensitivity adjustment, filtering, baseline or drift compensation
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02N—ELECTRIC MACHINES NOT OTHERWISE PROVIDED FOR
- H02N1/00—Electrostatic generators or motors using a solid moving electrostatic charge carrier
- H02N1/04—Friction generators
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B2560/00—Constructional details of operational features of apparatus; Accessories for medical measuring apparatus
- A61B2560/02—Operational features
- A61B2560/0204—Operational features of power management
- A61B2560/0214—Operational features of power management of power generation or supply
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B2562/00—Details of sensors; Constructional details of sensor housings or probes; Accessories for sensors
- A61B2562/02—Details of sensors specially adapted for in-vivo measurements
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- Health & Medical Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Engineering & Computer Science (AREA)
- Signal Processing (AREA)
- Medical Informatics (AREA)
- Animal Behavior & Ethology (AREA)
- Pathology (AREA)
- Physics & Mathematics (AREA)
- Biomedical Technology (AREA)
- Heart & Thoracic Surgery (AREA)
- Physiology (AREA)
- Molecular Biology (AREA)
- Surgery (AREA)
- Biophysics (AREA)
- General Health & Medical Sciences (AREA)
- Public Health (AREA)
- Veterinary Medicine (AREA)
- Artificial Intelligence (AREA)
- Computer Vision & Pattern Recognition (AREA)
- Psychiatry (AREA)
- Cardiology (AREA)
- Power Engineering (AREA)
- Measuring Pulse, Heart Rate, Blood Pressure Or Blood Flow (AREA)
Abstract
The invention discloses a kind of monitoring of pulse sensor, preparation method, pulse monitoring device and system, monitoring of pulse sensor includes: triboelectricity component and the first encapsulated layer and the second encapsulated layer for encapsulating triboelectricity component;Triboelectricity component includes: the first friction component and the second friction component being cascading;First friction component includes the first electrode layer being stacked and the first high polymer insulating layer, and the second friction component includes the second electrode lay;First encapsulated layer is arranged on surface of the first electrode layer far from the first high polymer insulating layer;Second encapsulated layer is arranged on surface of the second electrode lay far from the first friction component and on the side surface of triboelectricity component;Second encapsulated layer with the first concave-convex array structure is provided on the surface of user's skin contact.The technical solution improves the sensitivity of monitoring of pulse sensor, can accurately be monitored to the beat pulse of user, and structure and manufacture craft are simple, low in cost.
Description
Technical field
The present invention relates to measuring of human health fields, and in particular to a kind of monitoring of pulse sensor, preparation method, pulse prison
Survey apparatus and system.
Background technique
Pulse is one of important physiological parameter of human body, carries physiology and pathological information abundant, has important life
Reason reference and diagnosis reference value, for example, can be according to the heart of analyzing pulse human body, liver and gallbladder, health status of kidney etc..
With stepping up for living standard, people more recognize the importance of health, therefore, more and more users
(such as the elderly, cardiac function bad people) thirsts for being able to carry out permanently effective medical monitoring, suffer from for a long time for some
The people of heart disease or the old man of long-term bed are supervised in real time with greater need for some important vital signs (such as pulse) to them
It surveys, to be given first aid in time when emergency occurs.Therefore, monitoring of pulse sensor and device just come into being.
However existing monitoring of pulse sensor and device usually have that structure is complicated, complex manufacturing technology, manufacturing cost
Therefore height, monitoring inaccuracy, the defects such as sensitivity is low lack a kind of structure in the prior art and manufacture craft are simple, at low cost
The monitoring of pulse sensor and device of honest and clean, monitoring precision and high sensitivity.
Summary of the invention
Goal of the invention of the invention is in view of the drawbacks of the prior art, to provide a kind of monitoring of pulse sensor, preparation side
Method, pulse monitoring device and system, for solving monitoring of pulse sensor in the prior art and apparatus structure complexity, manufacture craft
Complexity, manufacturing cost is high, monitoring inaccuracy, the low problem of sensitivity.
The present invention provides a kind of monitoring of pulse sensors, comprising: triboelectricity component and for encapsulating triboelectricity portion
The first encapsulated layer and the second encapsulated layer of part;
It is human body that triboelectricity component, which is used to act on the beat pulse of user the pressure conversion on triboelectricity component,
Physiological signal output;Wherein, triboelectricity component includes: the first friction component and the second friction component being cascading;
First friction component includes the first electrode layer being stacked and the first high polymer insulating layer, and the second friction component includes
The second electrode lay;
First encapsulated layer is arranged on surface of the first electrode layer far from the first high polymer insulating layer;
Second encapsulated layer is arranged on surface of the second electrode lay far from the first friction component and triboelectricity component
On side surface;Second encapsulated layer with the first concave-convex array structure is provided on the surface of user's skin contact.
The present invention also provides a kind of preparation methods such as above-mentioned monitoring of pulse sensor, comprising:
Production first electrode layer and the first high polymer insulating layer are stacked gradually on the first encapsulated layer, obtain first
Friction component;
The second electrode lay is made, the second friction component is obtained;
First friction component and the second friction component are stacked together, obtain triboelectricity component, wherein first
Frictional interface is formed between friction component and the second friction component;
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of triboelectricity component, and
The second encapsulated layer is made on the side surface of triboelectricity component, obtains monitoring of pulse sensor.
The present invention also provides a kind of preparation methods such as above-mentioned monitoring of pulse sensor, comprising:
Stacking production first electrode layer and the first high polymer insulating layer, obtain the first friction component;
The second electrode lay is made, the second friction component is obtained;
First friction component and the second friction component are stacked together, obtain triboelectricity component, wherein first
Frictional interface is formed between friction component and the second friction component;
The first encapsulated layer is made in the first electrode layer of triboelectricity component;
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of triboelectricity component, and
The second encapsulated layer is made on the side surface of triboelectricity component, obtains monitoring of pulse sensor.
The present invention also provides a kind of pulse monitoring devices, comprising: at least one above-mentioned monitoring of pulse sensor, monitoring
Ontology and governor circuit module;Wherein,
At least one monitoring of pulse sensor is set to the inside and/or surface of monitoring ontology;
Governor circuit module is set to the internal or external of monitoring ontology;Governor circuit module and at least one monitoring of pulse
Sensor is connected, the physiology signal for being exported according at least one monitoring of pulse sensor, the arteries and veins of analytical calculation user
It fights parameter, obtains user's physiologic information.
The present invention also provides a kind of monitoring of pulse systems, comprising: such as above-mentioned pulse monitoring device and terminal device;
Wherein,
Terminal device is connected in a manner of wire communication or wireless communication with pulse monitoring device, for receiving and storing arteries and veins
User's physiologic information that monitoring device of fighting analytical calculation obtains is counted according to the user's physiologic information received, is used
Family physical condition, and/or send the control instruction for controlling pulse monitoring device.
The present invention also provides a kind of monitoring of pulse systems, comprising: such as above-mentioned pulse monitoring device and large database concept
Service platform;Wherein,
Pulse monitoring device is further used for: the user's physiologic information obtained according to analytical calculation counts, and is used
Family physical condition;
Large database concept service platform is connected in a manner of wire communication or wireless communication with pulse monitoring device, for receiving
And the user's body health status that pulse monitoring device counts is stored, by the user's body health status received and big number
Analysis comparison is carried out according to the user's body health status in the service platform of library, obtains customer analysis information, and customer analysis is believed
Breath is sent to pulse monitoring device.
Monitoring of pulse sensor provided by the invention, is realized using the first encapsulated layer and the second encapsulated layer to triboelectricity
Effective encapsulation of component, and the first concave-convex array structure is provided on the surface of the second encapsulated layer and user's skin contact,
The comfort level when compactness for increasing monitoring of pulse sensor and skin surface and user are using monitoring of pulse sensor, and
And the pressure conduction for being conducive to act on the beat pulse of user on the second encapsulated layer improves pulse to triboelectricity component
The sensitivity for monitoring sensor, can accurately be monitored the beat pulse of user, and have structure and manufacture craft letter
It is single, it is low in cost, it is suitble to the advantage of large-scale industrial production;Also, monitoring of pulse sensor provided by the invention uses first
Encapsulated layer and the second encapsulated layer realize effective encapsulation to triboelectricity component, omit shielding construction, are not only effectively reduced
Thickness of detector simplifies structure and manufacture craft, and compared with the monitoring of pulse sensor of setting shielding construction, reduces
The capacitor of device entirety, further improves the sensitivity of monitoring of pulse sensor.
In addition, the pulse monitoring device and system provided by the invention using above-mentioned monitoring of pulse sensor, passes through pulse
The beat pulse of user, is directly acted on the pressure on monitoring of pulse sensor by the beat pulse for monitoring sensor monitoring user
Physiology signal is converted to, the current physical condition of user is real-time and accurately reflected, is diagnosed to be user's in time
Disease avoids extraneous interference, improves the accuracy and reliability of monitoring.In addition, can by signal pre-processing module
Pulse signal is accurately extracted from the physiology signal that monitoring of pulse sensor exports, for subsequent pulse signal
Monitoring analysis, can be effectively removed the interference to monitoring of pulse, further improve the accuracy and reliability of monitoring.Separately
Outside, not only accuracy and reliability is high for pulse monitoring device provided by the invention and system, while also having structure and production work
The advantages of skill is simple, low in cost, is suitble to large-scale industrial production.Wherein, it is passed using triboelectricity component as monitoring of pulse
Sensor does not need external power supply and is powered to monitoring of pulse sensor, greatly saved the energy, protected environment;And
Triboelectricity component matter is soft, light-weight, improves comfort level when user uses.
Detailed description of the invention
Fig. 1 is the cross section structure schematic diagram of monitoring of pulse sensor embodiment one provided by the invention;
Fig. 2 is the cross section structure schematic diagram of monitoring of pulse sensor embodiment two provided by the invention;
Fig. 3 a is the structural schematic diagram using the pulse monitoring device embodiment of monitoring of pulse sensor provided by the invention;
Fig. 3 b is the functional structure frame using the pulse monitoring device embodiment of monitoring of pulse sensor provided by the invention
Figure;
Fig. 4 a is a functional structure frame of the signal pre-processing module embodiment one of pulse monitoring device provided by the invention
Figure;
Fig. 4 b is another functional structure of the signal pre-processing module embodiment one of pulse monitoring device provided by the invention
Block diagram;
Fig. 4 c is the another functional structure of the signal pre-processing module embodiment one of pulse monitoring device provided by the invention
Block diagram;
Fig. 4 d is another functional structure of the signal pre-processing module embodiment one of pulse monitoring device provided by the invention
Block diagram;
Fig. 5 is the functional block diagram of the signal pre-processing module embodiment two of pulse monitoring device provided by the invention;
Fig. 6 is the functional block diagram of the signal pre-processing module embodiment three of pulse monitoring device provided by the invention;
Fig. 7 is a functional structure of the monitoring of pulse system of pulse monitoring device provided by the invention shown in application drawing 3b
Block diagram;
Fig. 8 is another function knot of the monitoring of pulse system of pulse monitoring device provided by the invention shown in application drawing 3b
Structure block diagram.
Specific embodiment
The present invention is done in detail by following specific embodiments for the purpose, feature and effect for fully understanding the present invention
Describe in detail bright, but the present invention is not restricted to this.
The present invention provides a kind of monitoring of pulse sensors, comprising: triboelectricity component and for encapsulating triboelectricity portion
The first encapsulated layer and the second encapsulated layer of part;Triboelectricity component is used to the beat pulse of user acting on triboelectricity component
On pressure conversion be physiology signal output;Wherein, triboelectricity component includes: the first friction group being cascading
Part and the second friction component;First friction component includes the first electrode layer being stacked and the insulation of the first high molecular polymer
Layer, the second friction component includes the second electrode lay;First encapsulated layer is arranged in first electrode layer far from the first high molecular polymer
On the surface of insulating layer;Second encapsulated layer is arranged on surface of the second electrode lay far from the first friction component and triboelectricity
On the side surface of component;Second encapsulated layer with the first concave-convex array structure is provided on the surface of user's skin contact.
Fig. 1 is the cross section structure schematic diagram of monitoring of pulse sensor embodiment one provided by the invention, as shown in Figure 1, arteries and veins
Fighting and monitoring sensor includes: triboelectricity component and the first encapsulated layer 110 and the second encapsulation for encapsulating triboelectricity component
Layer 120.
Wherein, triboelectricity component for being by the pressure conversion that the beat pulse of user acts on triboelectricity component
Physiology signal output.Triboelectricity component includes: the first friction component 101 and the second friction component being cascading
102.First friction component 101 includes the first electrode layer 1011 and the first high polymer insulating layer 1012 being stacked,
Second friction component 102 is the second electrode lay.As shown in Figure 1, the triboelectricity component is three-decker.
As shown in Figure 1, the first encapsulated layer 110 is arranged in first electrode layer 1011 far from the first high polymer insulating layer
On 1012 surface.Those skilled in the art can the material according to actual needs to the first encapsulated layer 110 be configured, herein not
It limits.For example, the first encapsulated layer 110 can for selected from dimethyl silicone polymer, polypropylene, polyvinyl chloride, Kynoar,
Polyimides, aniline-formaldehyde resin, polyformaldehyde, ethyl cellulose, polyamide, melamino-formaldehyde, polyethylene glycol succinate,
Cellulose, cellulose ethanoate, polyethylene glycol adipate, polydiallyl phthalate, fiber sponge, elastic polyurethane
Body, styrene-acrylonitrile copolymer copolymer, styrene-butadiene-copolymer, staple fibre, poly- methyl, methacrylate, polyvinyl alcohol,
Polyester, polyisobutene, polyurethane flexible sponge, polyethylene terephthalate, polyvinyl butyral, formaldehyde-phenol, chlorine
In buna, butadiene-propylene copolymer, natural rubber, polyacrylonitrile, acrylonitrile vinyl chloride and polyethylene the third diphenol carbonate
One kind.Preferably, the first encapsulated layer 110 can be dimethyl silicone polymer (PDMS), polypropylene (PP), poly terephthalic acid
The polymer materials such as glycol ester (PET), polyvinyl chloride (PVC), Kynoar (PVDF) and polyamide (PA).For the ease of
First encapsulated layer 110 is assembled on triboelectricity component or monitoring of pulse sensor is assembled on other component, first
Encapsulated layer 110 can have at least one layer of glue film.Preferably, the first encapsulated layer 110 can have glue film for one side or two-sided all have
The pet layer of glue film.
Second encapsulated layer 120 is arranged on surface of the second electrode lay 102 far from the first friction component 101.This field skill
Art personnel can the material according to actual needs to the second encapsulated layer 120 be configured, herein without limitation.Specifically, the second envelope
Filling layer 120 can be the materials such as PDMS, rubber or latex, but directly and skin contact due to the second encapsulated layer 120, preferably select
Select gas permeability and the good material of hypo-allergenic property.Preferably, the material of the second encapsulated layer 120 is PDMS of the silicon hydrogen ratio in 1:1.5,
This PDMS encapsulated layer can preferably be such that monitoring of pulse sensor is bonded with skin surface, improve monitoring of pulse sensor
Sensitivity.
The compactness of monitoring of pulse sensor and skin surface in order to further increase, the preferably pulse of monitoring user are jumped
It is dynamic, improve the sensitivity of monitoring of pulse sensor, the second encapsulated layer 120 be provided with first on the surface of user's skin contact
Concave-convex array structure 130.The setting of first concave-convex array structure 130 can be conducive to the beat pulse of user acting on second
Pressure conduction on encapsulated layer 120 improves the sensitivity of monitoring of pulse sensor to triboelectricity component.In addition, first is recessed
The setting of convex array structure 130 additionally aids the comfort level for increasing user using monitoring of pulse sensor when, can effectively prevent
Only skin perspiration causes the skin area covered by monitoring of pulse sensor uncomfortable, further increases gas permeability.
Wherein, the first concave-convex array structure 130 can for grade not, the structure of micron level or Nano grade, first
The specific size range of concave-convex array structure 130 is 5nm to 3mm.First concave-convex array structure 130 may include with the one of flowering structure
Kind is a variety of: the bulge-structure of preset shape, the sunk structure of preset shape, banded structure, dermatoglyph shape striped, nano wire
Structure, nanocrystalline structure, nanorod structure and nano tube structure.First concave-convex array structure 130 may also include other structures,
Those skilled in the art can be configured according to actual needs, herein without limitation.For example, preset shape can for hemispherical,
Cylindrical, prismatic or pyramid etc..Specifically, bulge-structure can be constituted according to shaped formations such as rectangle or diamond shapes, band-like
Structure can be arranged in two sides, quadrangle, the edge of the second encapsulated layer 120 and the surface of user's skin contact according to geometry
Or in whole surface, for example, banded structure can be arranged according to the array of shapes of well word, fork word, zebra line style, cross or mouth word
Column.Wherein, dermatoglyph shape striped is and the approximate striped of dermatoglyph.
Optionally, in order to comprehensively be packaged to triboelectricity component, the second encapsulated layer 120 is also used to encapsulate friction hair
The side surface of electrical components.As shown in Figure 1, the second encapsulated layer 120 is additionally arranged on the side surface of triboelectricity component.
Monitoring of pulse sensor provided by the invention, is realized using the first encapsulated layer and the second encapsulated layer to triboelectricity
Effective encapsulation of component, and the first concave-convex array structure is provided on the surface of the second encapsulated layer and user's skin contact,
The comfort level when compactness for increasing monitoring of pulse sensor and skin surface and user are using monitoring of pulse sensor, and
And be conducive to the pressure conduction beat pulse of user acted on the second encapsulated layer to triboelectricity component, to improve
The sensitivity of monitoring of pulse sensor can accurately be monitored the beat pulse of user;Also, arteries and veins provided by the invention
It fights and monitors sensor effective encapsulation to triboelectricity component is realized using the first encapsulated layer and the second encapsulated layer, omit shielding
Structure not only significantly reduces thickness of detector, simplifies structure and manufacture craft, and supervise with the pulse of setting shielding construction
It surveys sensor to compare, reduces the capacitor of device entirety, further improve the sensitivity of monitoring of pulse sensor.
In the present invention, triboelectricity component can be three-decker in the prior art, four-layer structure, five layers thin between two parties
Membrane structure or five layers of intervening electrode structure, above-mentioned triboelectricity component include at least two opposite faces for constituting frictional interface, rub
Wiping electrical generation components has signal output end.In order to increase comfort level when use and monitoring of pulse sensor and user's skin
Compactness, it is preferred to use flexible friction electrical generation components.It is constituted in triboelectricity component in two surfaces of frictional interface at least
The second concave-convex array structure is provided on one surface.Wherein, the second concave-convex array structure is multiple salient points according to rectangle or water chestnut
Shape is arranged to make up, or is arranged in the two sides, quadrangle, surrounding at least one surface according to geometry for multiple banded structures
On edge or whole surface.Optionally, the shape of salient point can be hemispherical, cylinder, prismatic or pyramid etc., not do herein
It is specific to limit;Banded structure can be arranged according to the array of shapes of well word, fork word, zebra line style, cross or mouth word, not done herein
It is specific to limit.
Specifically, when triboelectricity component is three-decker, the first friction component includes the first electrode being stacked
Layer and the first high polymer insulating layer, the second friction component include the second electrode lay, first electrode layer and the first macromolecule
Two opposite surfaces of polymer insulation layer and/or the first high polymer insulating layer two tables opposite with the second electrode lay
Face constitutes frictional interface, and first electrode layer and the second electrode lay are signal output end.
When triboelectricity component is four-layer structure, the first friction component includes the first electrode layer being stacked and first
High polymer insulating layer, the second friction component include the second high polymer insulating layer and second electrode being stacked
Layer, the first high polymer insulating layer two surfaces opposite with the second high polymer insulating layer constitute frictional interface,
First electrode layer and the second electrode lay are signal output end.
When triboelectricity component is five layers of membrane structure between two parties, the first friction component includes the first electrode being stacked
Layer, the first high polymer insulating layer and film layer, the second friction component include the second polyphosphazene polymer being stacked between two parties
Close object insulating layer and the second electrode lay, the first high polymer insulating layer two surfaces opposite with film layer between two parties and/or
Film layer two surfaces opposite with the second high polymer insulating layer constitute frictional interface, first electrode layer and second between two parties
Electrode layer is signal output end.
When triboelectricity component is five layers of intervening electrode structure, the first friction component includes the first electrode being stacked
Layer, the first high polymer insulating layer and intervening electrode layer, the second friction component include the second polyphosphazene polymer being stacked
Close object insulating layer and the second electrode lay, the first high polymer insulating layer two surfaces opposite with intervening electrode layer and/or
Intervening electrode layer two surface opposite with the second high polymer insulating layer constitute frictional interface, and intervening electrode layer is one
Signal output end, first electrode layer and the second electrode lay are connected to another signal output end.
Fig. 2 is the cross section structure schematic diagram of monitoring of pulse sensor embodiment two provided by the invention, as shown in Fig. 2, arteries and veins
Fighting and monitoring sensor includes: triboelectricity component and the first encapsulated layer 110 and the second encapsulation for encapsulating triboelectricity component
Layer 120.In the present embodiment, triboelectricity component is four-layer structure, and triboelectricity component includes: first to be cascading
Friction component 201 and the second friction component 202, wherein the first friction component 201 includes the first electrode layer being cascading
2011 and first high polymer insulating layer 2012, the second friction component 202 include the second macromolecule being cascading
Polymer insulation layer 2021 and the second electrode lay 2022, the first high polymer insulating layer 2012 and the second high molecular polymer
Two opposite surfaces of insulating layer 2021 constitute frictional interface, first electrode layer 2011 and the second electrode lay 2022 as signal output
End.
In order to which make can between the first high polymer insulating layer 2012 and the second high polymer insulating layer 2021
Friction is better contacted with, the hemispheric second concave-convex array structure can be provided in the first high polymer insulating layer 2012
2013.When the first high polymer insulating layer 2012 and the contact friction of the second high polymer insulating layer 2021, second
Concave-convex array structure 2013 can make the first high polymer insulating layer 2012 and the second high polymer insulating layer 2021
Apparent surface better contact with friction, and induce more electricity at first electrode layer 2011 and the second electrode lay 2022
Lotus, the shape of protrusion is not limited to hemispherical certainly, can also be for cylindrical, prismatic and pyramid etc., and size can be nanometer, micro-
Rice or millimeter rank etc..
Surface of the first electrode layer 2011 far from the first high polymer insulating layer 2012 is arranged in first encapsulated layer 110
On.Second encapsulated layer 120 is arranged on surface of the second electrode lay 2022 far from the first friction component 201, is additionally arranged at friction
On the side surface of electrical generation components.The compactness of monitoring of pulse sensor and skin surface in order to further increase, preferably monitors
The beat pulse of user, relaxing when improving the sensitivity of monitoring of pulse sensor, and increasing user using monitoring of pulse sensor
The beat pulse of user is preferably acted on the pressure conduction on the second encapsulated layer 120 to triboelectricity component by appropriateness, and second
Encapsulated layer 120 with the first concave-convex array structure 130 is provided on the surface of user's skin contact.
Optionally, in the above embodiments, the shape of monitoring of pulse sensor can be with rectangle, circle, square, this
Field technical staff, which can according to need, to be selected, herein without limitation.Wherein, monitoring of pulse sensor is preferably shaped to
Rectangle, length × wide size are chosen as 15mm × 6.0mm or 15mm × 7.4mm.
The present invention also provides two different preparation methods of the monitoring of pulse sensor for the various embodiments described above.Its
In, the first preparation method includes: that production first electrode layer and the first high molecular polymer are stacked gradually on the first encapsulated layer
Insulating layer obtains the first friction component;The second electrode lay is made, the second friction component is obtained;By the first friction component and second
Friction component is stacked together, obtains triboelectricity component, wherein shape between the first friction component and the second friction component
At frictional interface;Production is provided with the second encapsulation of the first concave-convex array structure on the second electrode lay of triboelectricity component
Layer, and the second encapsulated layer is made on the side surface of triboelectricity component, obtain monitoring of pulse sensor.Second of preparation method
Include: to stack gradually production first electrode layer and the first high polymer insulating layer, obtains the first friction component;Production second
Electrode layer obtains the second friction component;First friction component and the second friction component are stacked together, friction hair is obtained
Electrical components, wherein form frictional interface between the first friction component and the second friction component;In the first electricity of triboelectricity component
The first encapsulated layer is made on the layer of pole;Production is provided with the first concave-convex array structure on the second electrode lay of triboelectricity component
Second encapsulated layer, and the second encapsulated layer is made on the side surface of triboelectricity component, obtain monitoring of pulse sensor.
Optionally, in order to enable triboelectricity component to better contact with friction, more charges are induced, it can be first
The concave-convex array structure of production second on frictional interface is formed by between friction component and the second friction component.With triboelectricity portion
It, can be in the first high polymer insulating layer of the first friction component and/or the second friction component for part is four-layer structure
The second high polymer insulating layer on the concave-convex array structure of production second so that the first high polymer insulating layer
And second can better contact with friction between high polymer insulating layer, and feel at first electrode layer and the second electrode lay
More charge should be gone out.
Specifically, spin coating proceeding, silk-screen printing technique, InkJet printing processes, magnetron sputtering technique or vapor deposition work can be passed through
Skill realizes the production to first electrode layer and the second electrode lay, and those skilled in the art can select specifically to make according to actual needs
Make technique production first electrode layer and the second electrode lay, herein without limitation.Spin coating proceeding, casting technique, coating work can be passed through
Skill, Shooting Technique, heat pressing process, spraying process, silk-screen printing technique, InkJet printing processes, magnetron sputtering technique or vapor deposition work
Skill realizes the production to the first high polymer insulating layer and the second high polymer insulating layer, and those skilled in the art can
Specific manufacture craft is selected according to the nature of polymer material, herein without limitation.For example, the Shooting Technique system of can be used
Make the first high polymer insulating layer and the second high polymer insulating layer that material is PET.In addition, in the first electricity of production
During pole layer and the second electrode lay, it also may be selected to be made using conductive metal film or radio frequency film;?
During making the first high polymer insulating layer and the second high polymer insulating layer, it may be selected to utilize polymer thin
Film is made.
Optionally, using template or etching technics the second of triboelectricity component in above two preparation method
Production is provided with the second encapsulated layer of the first concave-convex array structure on electrode layer.Wherein, using template in triboelectricity component
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay specifically: obtains a side surface and presets
There is the template of the first concave-convex array structure, wherein template can be the materials such as acrylic, stainless steel, aluminium alloy, quartz or glass
Material then makes the second encapsulated layer on surface of the template far from the first concave-convex array structure by spin coating proceeding, then will rub
It wipes electrical generation components to be arranged on the second encapsulated layer, triboelectricity component is made to be provided with a side surface and the second envelope of the second electrode lay
Dress layer is in contact, and the side surface of triboelectricity component is made to be in contact with the second encapsulated layer, finally adds to the second encapsulated layer
Heat cure is simultaneously cut, and obtains monitoring of pulse sensor, is sent out to be realized by the first encapsulated layer and the second encapsulated layer friction
Whole encapsulation of electrical components outer surface.It is made on the second electrode lay of triboelectricity component using etching technics and is provided with first
Second encapsulated layer of concave-convex array structure specifically: by spin coating proceeding, i.e., triboelectricity component is provided with the second electrode lay
Surface on and the side surface of triboelectricity component on coating PDMS make the second encapsulated layer, the second encapsulated layer heat solid
Change and cut, then the concave-convex array structure of etching first on the second encapsulated layer, obtains monitoring of pulse sensor.
It is introduced below by two kind preparation methods of the specific embodiment to monitoring of pulse sensor, wherein in the reality
It applies in example, the triboelectricity component in monitoring of pulse sensor is four-layer structure.
The first preparation method:
Step 101, first that the first encapsulated layer (such as PP film) is horizontal fixed during preparing monitoring of pulse sensor
It is laid on station.When the first encapsulated layer is the material of lighter weight, such as thin-film material, for the ease of first is encapsulated
Layer fixation is laid on station, glue film can be arranged close to the surface of station in the first encapsulated layer, then glue film in order to prevent
It sticks on station and glue film is prevented to be contaminated, release paper can be first laid on station, then again by the first encapsulation
The horizontal fixation of layer is laid on station.
Step 102, it according to the pre-set dimension of monitoring of pulse sensor, is splashed on the first encapsulated layer by magnetron sputtering technique
Material gold production first electrode layer is penetrated, cutting processing is carried out to PET film according to the pre-set dimension of monitoring of pulse sensor, will be cut out
Then first high polymer insulating layer is adhered to as the first high polymer insulating layer by the PET film after cutting
On one side surface of one electrode layer, to obtain the first friction component.
Step 103, cutting processing is carried out to PVC film according to the pre-set dimension of monitoring of pulse sensor, after cutting
PVC film is as the second high polymer insulating layer, by magnetron sputtering technique in the second high polymer insulating layer
Sputter material gold makes the second electrode lay on one side surface, to obtain the second friction component.
Step 104, the first friction component and the second friction component are stacked together, obtain triboelectricity component,
Wherein, the second high molecular polymer of the first high polymer insulating layer of the first friction component and the second friction component insulate
Frictional interface is formed between layer.
Step 1051, the first concave-convex array is provided with if making on the second electrode lay of triboelectricity component using template
Second encapsulated layer of structure then obtains the template that a side surface is previously provided with the first concave-convex array structure, then passes through spin coating
Technique coating PDMS on surface of the template far from the first concave-convex array structure makes the second encapsulated layer, and triboelectricity component is set
It sets on the second encapsulated layer, the side surface for making triboelectricity component be provided with the second electrode lay is in contact with the second encapsulated layer,
And the side surface of triboelectricity component is made to be in contact with the second encapsulated layer, then the second encapsulated layer is heating and curing and is cut
Processing, obtains monitoring of pulse sensor.
Step 1052, the first bumps are provided with if making on the second electrode lay of triboelectricity component using etching technics
Second encapsulated layer of array structure, then through spin coating proceeding on the second electrode lay of triboelectricity component and triboelectricity component
Side surface on coating PDMS make the second encapsulated layer, be then heating and curing to the second encapsulated layer and cutting processing, then
The concave-convex array structure (such as nanowire structure) of etching first, obtains monitoring of pulse sensor on the second encapsulated layer.
Second of preparation method:
Step 201, cutting processing is carried out to PET film according to the pre-set dimension of monitoring of pulse sensor, after cutting
Then PET film is insulated by magnetron sputtering technique in the first high molecular polymer as the first high polymer insulating layer
Sputter material gold makes first electrode layer on one side surface of layer, to obtain the first friction component.
Step 202, cutting processing is carried out to PVC film according to the pre-set dimension of monitoring of pulse sensor, after cutting
Then PVC film is insulated by magnetron sputtering technique in the second high molecular polymer as the second high polymer insulating layer
Sputter material gold makes the second electrode lay on one side surface of layer, to obtain the second friction component.
Step 203, the first friction component and the second friction component are stacked together, obtain triboelectricity component,
Wherein, the second high molecular polymer of the first high polymer insulating layer of the first friction component and the second friction component insulate
Frictional interface is formed between layer.
Step 204, it selects one side to have the PP film of glue film as the first encapsulated layer, the first encapsulated layer is had into glue film
It is adhered in the first electrode layer of triboelectricity component on one side.
Step 2051, the first concave-convex array is provided with if making on the second electrode lay of triboelectricity component using template
Second encapsulated layer of structure then obtains the template that a side surface is previously provided with the first concave-convex array structure, then passes through spin coating
Technique coating PDMS on surface of the template far from the first concave-convex array structure makes the second encapsulated layer, and triboelectricity component is set
It sets on the second encapsulated layer, the side surface for making triboelectricity component be provided with the second electrode lay is in contact with the second encapsulated layer,
And the side surface of triboelectricity component is made to be in contact with the second encapsulated layer, then the second encapsulated layer is heating and curing and is cut
Processing, obtains monitoring of pulse sensor.
Step 2052, the first bumps are provided with if making on the second electrode lay of triboelectricity component using etching technics
Second encapsulated layer of array structure, then through spin coating proceeding on the second electrode lay of triboelectricity component and triboelectricity component
Side surface on coating PDMS make the second encapsulated layer, be then heating and curing to the second encapsulated layer and cutting processing, then
The concave-convex array structure (such as nanowire structure) of etching first, obtains monitoring of pulse sensor on the second encapsulated layer.
If triboelectricity component in prepared monitoring of pulse sensor be three-decker, five layers between two parties membrane structure or
Five layers of intervening electrode structure, preparation process and above-mentioned preparation include that the monitoring of pulse of the triboelectricity component of four-layer structure passes
The preparation process of sensor is similar.It include the preparation of the monitoring of pulse sensor of the triboelectricity component of four-layer structure with preparation
Journey is compared, for include three-decker triboelectricity component monitoring of pulse sensor preparation, can rub in production second
The second high polymer insulating layer is saved during brush assembly;For including five layers, membrane structure or five layers are between two parties between two parties
The preparation of the monitoring of pulse sensor of the triboelectricity component of electrode structure, can be during making triboelectricity component in addition
An interlayer is made, interlayer is film layer or intervening electrode layer between two parties, and interlayer is then assembled in the first friction component
The first high polymer insulating layer on or be assembled in the second high polymer insulating layer of the second friction component, so
The first friction component and the second friction component are stacked together afterwards, obtain triboelectricity component, wherein the first friction group
Frictional interface is formed between part and the second friction component.
The preparation method of above-mentioned monitoring of pulse sensor provided by the invention, passes through spin coating proceeding, silk-screen printing technique, spray
The techniques such as black printing technology, magnetron sputtering technique or evaporation process, which can be prepared, is provided with the first concave-convex array junctions on encapsulated layer
The monitoring of pulse sensor of structure.By the present invention in that being just convenient to obtain highly sensitive and high use with suitable preparation method
The monitoring of pulse sensor of comfort level, simple, the low-cost advantage with manufacture craft.
Fig. 3 a and Fig. 3 b are respectively the pulse monitoring device embodiment of application monitoring of pulse sensor provided by the invention
Structural schematic diagram and functional block diagram, as shown in Figure 3a and Figure 3b shows, pulse monitoring device include at least one above-mentioned pulse prison
Survey sensor 310, monitoring ontology 320 and governor circuit module 330.Wherein, monitoring ontology 320 can be wrist strap, bandage or glue
Film etc., those skilled in the art can according to actual needs be configured the structure for monitoring ontology 320.Herein without limitation.
At least one monitoring of pulse sensor 310 is set to the inside and/or surface of monitoring ontology 320, is used for user
Beat pulse effect pressure conversion on it be that physiology signal exports.Specifically, the number of monitoring of pulse sensor 310
Amount can be one, or multiple, those skilled in the art can be according to actual needs to monitoring of pulse sensor 310
Specific set-up mode is selected, herein without limitation.As shown in Figure 3a, in the present embodiment, to monitor ontology 320 as bandage
For, bandage is strapped in the wrist portion of user, and monitoring of pulse sensor 310 can be removeably positioned at wrist strap and use
On one side surface of the wrist portion contact at family, this setup can be convenient for user accurately by monitoring of pulse sensor 310
It is arranged at the train of thought of wrist portion, is preferably bonded with wrist portion, so as to preferably monitors beat pulse.
In a specific embodiment, since the number that the number of human pulse bounce is beated with human heart is consistent
, therefore the number for monitoring human pulse bounce is able to reflect out the number of human heart bounce, then this only can monitored
A monitoring of pulse sensor 310 is arranged to monitor human pulse number the number of bounce (i.e. human heart) in body 320,
Multiple series connection and/or monitoring of pulse sensor 310 after being connected in parallel can be set in monitoring ontology 320 to monitor human pulse
Number.
Governor circuit module 330 is set to the internal or external of monitoring ontology 320.Governor circuit module 330 and at least one
A monitoring of pulse sensor 310 is connected, the physiology signal for being exported according at least one monitoring of pulse sensor 310,
The Pulse-Parameters of analytical calculation user obtain user's physiologic information.
As shown in Figure 3b, governor circuit module 330 includes: signal pre-processing module 331, analog-to-digital conversion module 332, center
Control module 333, display module 334, interactive function module 335 and power module 336.Wherein, signal pre-processing module 331 with
At least one monitoring of pulse sensor 310 is connected, the Human Physiology letter for exporting at least one monitoring of pulse sensor 310
It number is pre-processed, obtains pulse signal;Analog-to-digital conversion module 332 is connected with signal pre-processing module 331, for signal is pre-
The pulse signal for the simulation that processing module 331 exports is converted to the pulse signal of number, wherein passes through signal pre-processing module
The pulse signal obtained after 331 pretreatments is that the pulse signal of simulation needs to pass through analog-to-digital conversion for subsequent analysis processing
The pulse signal of simulation is converted into being suitble to the pulse signal of the number of signal analysis and processing by module 332;Central control module 333
It is connected with analog-to-digital conversion module 332, the pulse signal of the number for being exported according to analog-to-digital conversion module 332, analytical calculation is used
The Pulse-Parameters at family obtain user's physiologic information, wherein Pulse-Parameters include the waveform feature parameter of pulse signal, such as maximum
Amplitude point etc., user's physiologic information include the information such as the beat pulse frequency, beat pulse amplitude, pulse wave feature of user;
Display module 334 is connected with central control module 333, the user's physiologic information exported for showing central control module 333;It hands over
Mutual functional module 335 is connected with central control module 333, for sending user's interactive instruction to central control module 333;Power supply
Module 336 is connected with interactive function module 335, for providing electric energy.
User can control power module 336 by interactive function module 335 and be connected to central control module 333, from
And central control module 333 is made to start to work.Specifically, user's interactive instruction includes open command, out code, user information
The instructions such as setting instruction.
Wherein, display screen used can be LCD display, OLED display screen etc. in display module 334, and concrete type can
To be selected according to the design of those skilled in the art, herein without limitation.
In addition, central control module 333 can be further used for: whether the Pulse-Parameters for the user that discriminatory analysis is calculated
Meet default Pulse-Parameters threshold value, and controlling alarm electric signal is exported according to judging result.Those skilled in the art can be according to reality
Border needs to set default Pulse-Parameters threshold value, herein without limitation.In this case, governor circuit module 330 is gone back
It include: alarm module 337;Wherein, alarm module 337 is connected with central control module 333, for according to central control module
The controlling alarm electric signal of 333 outputs carries out warning reminding.
Optionally, governor circuit module 330 further include: radio receiving transmitting module 338.Radio receiving transmitting module 338 and center are controlled
Molding block 333 is connected, and user's physiologic information for exporting central control module 333 is sent to end in a manner of wirelessly communicating
End equipment, so that the related personnel such as doctor and/or guardian consult.
Optionally, governor circuit module 330 can also further comprise memory module 339, and memory module 339 and center control
Module 333 is connected, for storing the process pretreated pulse of signal pre-processing module 331 of the output of central control module 333
User's physiologic information that signal and central control module 333 obtain.
Fig. 4 a is a functional structure frame of the signal pre-processing module embodiment one of pulse monitoring device provided by the invention
Figure, as shown in fig. 4 a, signal pre-processing module 331 include: charge amplification module 3311, voltage amplification module 3312 and band logical filter
Wave module 3313;Wherein, charge amplification module 3311 is connected at least one monitoring of pulse sensor 310, for at least one
The physiology signal that a monitoring of pulse sensor 310 exports carries out impedance transformation;Voltage amplification module 3312 and charge amplify
Module 3311 is connected, and the physiology signal for exporting charge amplification module 3311 carries out voltage amplification;Bandpass filtering mould
Block 3313 is connected with voltage amplification module 3312, and the physiology signal for exporting to voltage amplification module 3312 carries out band logical
Filtering processing, obtains pulse signal.
At least one monitoring of pulse sensor 310 is arranged in and can collect at the position of physiology signal, wherein people
Body physiological signal includes pulse signal, furthermore it is possible to include other signals, for example, breath signal, for by human pulse,
Breathing is converted to physiology signal output.At least one monitoring of pulse sensor 310 can detecte out human pulse, breathing etc.
The signal of physiological characteristic, output is to contain the superposed signal of the physiological characteristics such as pulse, breathing.In addition, due to monitoring of pulse
Sensor 310 is more sensitive for incuding the pulse of human body, breathing, and the voltage of output is also higher, this not only lowers rate of false alarm,
The requirement to subsequent module can also be reduced simultaneously, simplify circuit.
More faint simulation is generally by the physiology signal that at least one monitoring of pulse sensor 310 acquires
Pulse signal, and power frequency is generally doped in the physiology signal of at least one monitoring of pulse sensor 310 output
Interference signal etc., so, after collecting physiology signal, charge enhanced processing should be successively carried out to human body physiological signal
It is handled with voltage amplification, is same or similar (i.e. undistorted), the amplitude of a waveform according to default amplification factor obtained from
The physiology signal of increase, and then human body physiological signal is analyzed and processed convenient for subsequent modules.Specifically, sharp
With the charge amplification module 3311 being connected at least one monitoring of pulse sensor 310 at least one monitoring of pulse sensor
The physiology signal of 310 outputs carries out impedance transformation, to realize charge enhanced processing;According to charge amplification module 3311
Default amplification factor in connected voltage amplification module 3312, the physiology signal that charge amplification module 3311 is exported into
Row voltage amplification.
Since the signal of at least one monitoring of pulse sensor 310 output is to contain the physiological characteristics such as pulse, breathing
Superposed signal, and be still pulse, physiology of respiration in the physiology signal exported after the processing of voltage amplification module 3312
The superposed signal of feature, but pulse as human body, frequency domain locating for breath signal are often different, such as the pulse of human body
Signal is respectively at different frequency domains from breath signal, and human pulse signal frequency concentrates on [0.5Hz, 30Hz] frequency domain model
In enclosing, human body respiration signal frequency is concentrated in [0.05Hz, 0.4Hz] frequency domain, therefore, can preferentially select [0.5Hz,
30Hz] bandpass filter physiology signal that voltage amplification module 3312 is exported carry out bandpass filtering treatment, to realize
By the purpose of pulse signal separation and Extraction.
Optionally, bandpass filtering modules block 3313 further comprises: high pass filter unit 3301 and low-pass filter unit 3302;
Wherein, high pass filter unit 3301 is connected with voltage amplification module 3312, the human body for exporting to voltage amplification module 3312
Physiological signal carries out high-pass filtering processing, for example, can be made an uproar by 3301 rejection frequency of high pass filter unit 0.5Hz is below
Acoustic jamming signal;Low-pass filter unit 3302 is connected with high pass filter unit 3301, for exporting to high pass filter unit 3301
Physiology signal carry out low-pass filtering treatment, for example, can by 3302 rejection frequency of low-pass filter unit 30Hz with
On noise interferences, thus obtain frequency domain be [0.5Hz, 30Hz] pulse signal, can not only filter out exhale here
Signal etc. is inhaled, other noise interferences and power frequency interference signals can also be filtered out.
Although bandpass filtering modules block 3313 can filter out the power frequency interference signals of doping, due to being transmitted across in signal
Cheng Zhong, it is also possible to adulterate power frequency interference signals at any time, therefore, in order to obtain pure pulse signal, obtain pulse letter
After number, pulse signal can be exported to power frequency notch module 3314, to filter out bandpass filtering using power frequency notch module 3314
The power frequency interference signals in pulse signal that module 3313 exports.Specifically, in a kind of optional embodiment, such as Fig. 4 b institute
Show, which further includes power frequency notch module 3314;Power frequency notch module 3314 and bandpass filtering modules block 3313
It is connected, the power frequency interference signals in pulse signal for filtering out the output of bandpass filtering modules block 3313 obtain more pure arteries and veins
It fights signal.This kind of optional embodiment is (i.e. after carrying out bandpass filtering treatment to physiology signal, then to bandpass filtering treatment
Obtained pulse signal is filtered), interference of the power frequency interference signals to pulse signal, Neng Goubao can be effectively reduced
Card finally obtains more pure pulse signal, improves the extraction accuracy of pulse signal.
In addition, in this kind of optional embodiment, if bandpass filtering modules block 3313 further comprises: high pass filter unit
3301 and low-pass filter unit 3302, then high pass filter unit 3301 is connected with voltage amplification module 3312, for putting to voltage
The physiology signal that big module 3312 exports carries out high-pass filtering processing;Low-pass filter unit 3302 and high pass filter unit
3301 are connected, and the physiology signal for exporting to high pass filter unit 3301 carries out low-pass filtering treatment, obtain pulse letter
Number;Power frequency notch module 3314 is connected with low-pass filter unit 3302, for filtering out the pulse of the output of low-pass filter unit 3302
Power frequency interference signals in signal.
In another optional embodiment, as illustrated in fig. 4 c, signal pre-processing module 331 further includes power frequency notch module
3314;Power frequency notch module 3314 is connected with voltage amplification module 3312, for filtering out the people of the output of voltage amplification module 3312
Power frequency interference signals in body physiological signal, and output this to bandpass filtering modules block 3313.
In this kind of optional embodiment, if bandpass filtering modules block 3313 further comprises: 3301 He of high pass filter unit
Low-pass filter unit 3302, then power frequency notch module 3314 is connected with voltage amplification module 3312, for filtering out voltage amplification mould
The power frequency interference signals in physiology signal that block 3312 exports;High pass filter unit 3301 and 3314 phase of power frequency notch module
Even, the physiology signal for exporting to power frequency notch module 3314 carries out high-pass filtering processing;Low-pass filter unit 3302
It is connected with high pass filter unit 3301, the physiology signal for exporting to high pass filter unit 3301 carries out at low-pass filtering
Reason, obtains pulse signal.
In the present embodiment, raw using triboelectricity component acquisition human body due at least one monitoring of pulse sensor 310
Signal is managed, therefore, the physiology signal of at least one monitoring of pulse sensor 310 output is the pulse signal of simulation,
That is, in the physiology signal of at least one monitoring of pulse sensor 310 output, there are negative amplitudes.Therefore, in order to
Simplify the analysis treatment process of subsequent module and guarantee the accuracy rate of the analysis and processing result of subsequent module, needs at least one
The datum mark for the physiology signal that a monitoring of pulse sensor 310 exports is adjusted, and avoids the generation of negative amplitude.Specifically
Ground, the human body that can be exported using the adjustment module 3315 of benchmark shown in Fig. 4 d at least one monitoring of pulse sensor 310 are raw
The datum mark of reason signal is adjusted, that is to say, that signal pre-processing module 331 may also include benchmark adjustment module 3315;Base
Quasi- adjustment module 3315 is connected at least one monitoring of pulse sensor 310, for adjusting at least one monitoring of pulse sensor
The datum mark of the physiology signal of 310 outputs, and output this to charge amplification module 3311.
Signal pre-processing module provided in an embodiment of the present invention can accurately extract pulse signal, for subsequent
The monitoring of pulse signal is analyzed, and the signal pre-processing module structure is simple, and cost of manufacture is cheap, is suitble to heavy industrialization
Production.
Fig. 5 is the functional block diagram of the signal pre-processing module embodiment two of pulse monitoring device provided by the invention,
As shown in figure 5, signal pre-processing module 431 includes: charge amplification module 3311, voltage amplification module 3312, bandpass filtering mould
Block 3313, power frequency notch module 3314 and benchmark adjust module 3315;Wherein, benchmark adjustment module 3315 and at least one pulse
It monitors sensor 310 to be connected, the benchmark of the physiology signal for adjusting the output of at least one monitoring of pulse sensor 310
Point;Charge amplification module 3311 is connected with benchmark adjustment module 3315, and the human body for exporting to benchmark adjustment module 3315 is raw
It manages signal and carries out impedance transformation;Voltage amplification module 3312 is connected with charge amplification module 3311, is used for charge amplification module
The physiology signal of 3311 outputs carries out voltage amplification;Bandpass filtering modules block 3313 is connected with voltage amplification module 3312, uses
Bandpass filtering treatment is carried out in the physiology signal exported to voltage amplification module 3312, obtains pulse signal;Power frequency notch
Module 3314 is connected with bandpass filtering modules block 3313, the power frequency in pulse signal for filtering out the output of bandpass filtering modules block 3313
Interference signal.
In the present embodiment, raw using triboelectricity component acquisition human body due at least one monitoring of pulse sensor 310
Signal is managed, therefore, the physiology signal of at least one monitoring of pulse sensor 310 output is the pulse signal of simulation,
That is, in the physiology signal of at least one monitoring of pulse sensor 310 output, there are negative amplitudes.Therefore, in order to
Simplify the analysis treatment process of subsequent module and guarantee the accuracy rate of the analysis and processing result of subsequent module, needs at least one
The datum mark for the physiology signal that a monitoring of pulse sensor 310 exports is adjusted, and avoids the generation of negative amplitude.Specifically
Ground, the physiology signal that at least one monitoring of pulse sensor 310 is exported using benchmark shown in fig. 5 adjustment module 3315
Datum mark be adjusted;Wherein, benchmark adjustment module 3315 is connected at least one monitoring of pulse sensor 310, for adjusting
The datum mark of the physiology signal of whole at least one monitoring of pulse sensor 310 output, and output this to charge amplification mould
Block 3311.
More faint simulation is generally by the physiology signal that at least one monitoring of pulse sensor 310 acquires
Pulse signal, and power frequency is generally doped in the physiology signal of at least one monitoring of pulse sensor 310 output
Interference signal etc., so, it is raw adjusting the human body that module 3315 exports at least one monitoring of pulse sensor 310 by benchmark
After reason signal has adjusted datum mark, charge enhanced processing and voltage amplification processing should be successively carried out to human body physiological signal, from
Obtained to be same or similar (i.e. undistorted), the amplitude of a waveform believe according to the Human Physiology that default amplification factor increases
Number, and then human body physiological signal is analyzed and processed convenient for subsequent modules.Specifically, module is adjusted using with benchmark
The physiology signal that 3315 connected charge amplification modules 3311 export benchmark adjustment module 3315 carries out impedance transformation, from
And realize charge enhanced processing;According to the default times magnification in the voltage amplification module 3312 being connected with charge amplification module 3311
Number, the physiology signal that charge amplification module 3311 is exported carry out voltage amplification.
Wherein, in the present embodiment in the description of bandpass filtering modules block 3313 and signal pre-processing module embodiment one to figure
The description of bandpass filtering modules block 3313 shown in 4a is identical, can refer in signal pre-processing module embodiment one to shown in Fig. 4 a
Bandpass filtering modules block 3313 description, details are not described herein again.
Although bandpass filtering modules block 3313 can filter out the power frequency interference signals of doping, due to being transmitted across in signal
Cheng Zhong, it is also possible to adulterate power frequency interference signals at any time, therefore, in order to obtain pure pulse signal, obtain pulse letter
After number, pulse signal is exported to power frequency notch module 3314, to filter out bandpass filtering modules block using power frequency notch module 3314
Power frequency interference signals in the pulse signal of 3313 outputs.Specifically, power frequency notch module 3314 and bandpass filtering modules block 3313
It is connected, the power frequency interference signals in pulse signal for filtering out the output of bandpass filtering modules block 3313 obtain more pure arteries and veins
It fights signal.It is carried out after carrying out bandpass filtering treatment to physiology signal, then to the pulse signal that bandpass filtering treatment obtains
Filtering processing, can effectively reduce interference of the power frequency interference signals to pulse signal, can guarantee to finally obtain more pure
Pulse signal, improve the extraction accuracy of pulse signal.
In addition, if bandpass filtering modules block 3313 further comprises: high pass filter unit 3301 and low-pass filter unit 3302,
Then high pass filter unit 3301 is connected with voltage amplification module 3312, the Human Physiology for exporting to voltage amplification module 3312
Signal carries out high-pass filtering processing;Low-pass filter unit 3302 is connected with high pass filter unit 3301, for high-pass filtering list
The physiology signal of 3301 output of member carries out low-pass filtering treatment, obtains pulse signal;Power frequency notch module 3314 and low pass
Filter unit 3302 is connected, the power frequency interference signals in pulse signal for filtering out the output of low-pass filter unit 3302.
Fig. 6 is the functional block diagram of the signal pre-processing module embodiment three of pulse monitoring device provided by the invention,
As shown in fig. 6, signal pre-processing module 531 includes: charge amplification module 3311, voltage amplification module 3312, bandpass filtering mould
Block 3313, power frequency notch module 3314 and benchmark adjust module 3315;Wherein, benchmark adjustment module 3315 and at least one pulse
It monitors sensor 310 to be connected, the benchmark of the physiology signal for adjusting the output of at least one monitoring of pulse sensor 310
Point;Charge amplification module 3311 is connected with benchmark adjustment module 3315, and the human body for exporting to benchmark adjustment module 3315 is raw
It manages signal and carries out impedance transformation;Voltage amplification module 3312 is connected with charge amplification module 3311, is used for charge amplification module
The physiology signal of 3311 outputs carries out voltage amplification;Power frequency notch module 3314 is connected with voltage amplification module 3312, uses
Power frequency interference signals in the physiology signal for filtering out the output of voltage amplification module 3312;Bandpass filtering modules block 3313 and work
Frequency notch module 3314 is connected, and the physiology signal for exporting to power frequency notch module 3314 carries out bandpass filtering treatment,
Obtain pulse signal.
Wherein, to benchmark adjustment module 3315, charge amplification module 3311 and voltage amplification module 3312 in the present embodiment
Description its can respectively correspond in contrast signal preprocessing module embodiment two to benchmark shown in fig. 5 adjustment module 3315, electricity
The description of lotus amplification module 3311 and voltage amplification module 3312, details are not described herein again.
More faint simulation is generally by the physiology signal that at least one monitoring of pulse sensor 310 acquires
Pulse signal, and power frequency is generally doped in the physiology signal of at least one monitoring of pulse sensor 310 output
Interference signal etc., so, after collecting physiology signal, charge enhanced processing should be successively carried out to human body physiological signal
It is handled with voltage amplification, is same or similar (i.e. undistorted), the amplitude of a waveform according to default amplification factor obtained from
The physiology signal of increase, and then human body physiological signal is analyzed and processed convenient for subsequent modules.Specifically, sharp
With the charge amplification module 3311 being connected at least one monitoring of pulse sensor 310 at least one monitoring of pulse sensor
The physiology signal of 310 outputs carries out impedance transformation, to realize charge enhanced processing;Using with charge amplification module 3311
The physiology signal that connected voltage amplification module 3312 exports charge amplification module 3311 carries out voltage amplification processing.
Although being exaggerated processing to physiology signal, it is dry to reduce the power frequency being entrained in human body physiological signal
The influence to human body physiological signal such as signal is disturbed, still, still will affect the accuracy for extracting pulse signal, therefore, right
After physiology signal enhanced processing, need to filter out the human body of the output of voltage amplification module 3312 by power frequency notch module 3314
Power frequency interference signals in physiological signal, to further decrease the power frequency interference signals etc. being entrained in human body physiological signal
Influence to human body physiological signal.Specifically, power frequency notch module 3314 is connected with voltage amplification module 3312, for filtering out
The power frequency interference signals in physiology signal that voltage amplification module 3312 exports, and output this to bandpass filtering modules block
3313。
Since the signal of at least one monitoring of pulse sensor 310 output is to contain the physiological characteristics such as pulse, breathing
Superposed signal, and be still pulse, physiology of respiration in the physiology signal exported after the processing of power frequency notch module 3314
The superposed signal of feature, but pulse as human body, frequency domain locating for breath signal are often different, such as the pulse of human body
Signal is respectively at different frequency domains from breath signal, and human pulse signal frequency concentrates on [0.5Hz, 30Hz] frequency domain model
In enclosing, human body respiration signal frequency is concentrated in [0.05Hz, 0.4Hz] frequency domain, therefore, can preferentially select [0.5Hz,
30Hz] bandpass filter physiology signal that voltage amplification module 3312 is exported carry out bandpass filtering treatment, to realize
By the purpose of pulse signal separation and Extraction.
Optionally, bandpass filtering modules block 3313 further comprises: high pass filter unit 3301 and low-pass filter unit 3302;
Wherein, high pass filter unit 3301 is connected with power frequency notch module 3314, the human body for exporting to power frequency notch module 3314
Physiological signal carries out high-pass filtering processing, for example, can be made an uproar by 3301 rejection frequency of high pass filter unit 0.5Hz is below
Acoustic jamming signal;Low-pass filter unit 3302 is connected with high pass filter unit 3301, for exporting to high pass filter unit 3301
Physiology signal carry out low-pass filtering treatment, for example, can by 3302 rejection frequency of low-pass filter unit 30Hz with
On noise interferences, thus obtain frequency domain be [0.5Hz, 30Hz] pulse signal, this can not only filter out breathing
Signal etc. can also filter out other noise interferences and power frequency interference signals.
In the embodiment of above-mentioned each signal pre-processing module, power frequency notch module is specifically as follows active double T band resistances
Filter, those skilled in the art, which can according to need, to be selected, herein without limitation.
Fig. 7 is a functional structure of the monitoring of pulse system of pulse monitoring device provided by the invention shown in application drawing 3b
Block diagram, as shown in fig. 7, the monitoring of pulse system includes: pulse monitoring device 710 and terminal device 720.Wherein, the pulse
Monitoring device 710 is pulse monitoring device shown in Fig. 3 b;Terminal device 720 and pulse monitoring device 710 with wire communication or
The mode of wireless communication is connected, the user's physiologic information obtained for receiving and storing 710 analytical calculation of pulse monitoring device, root
It is counted according to the user's physiologic information received, obtains user's body health status, and/or send for controlling monitoring of pulse
The control instruction of device 710.Wherein, user's body health status includes the healthy shape of heart, liver and gallbladder, kidney, lung, taste etc.
Condition.
Specifically, as shown in fig. 7, terminal device 720 in a manner of wireless communication with it is wireless in pulse monitoring device 710
Transceiver module 338 is connected, user's physiology letter that the central control module 333 for receiving the transmission of radio receiving transmitting module 338 obtains
Breath, counts according to the user's physiologic information received, obtains user's body health status, and send for controlling pulse
The control instruction of monitoring device 710.Wherein, control instruction can include: the unlatching for opening the work of central control module 333 refers to
The command for stopping for enabling and working for terminating central control module 333.Wherein, terminal device 720 can set for mobile phone, computer etc.
It is standby, and can be by completing the work of counting user physical condition, ability wherein designing specific application program
Field technique personnel, which can according to need, to be selected, herein without limitation.
Fig. 8 is another function knot of the monitoring of pulse system of pulse monitoring device provided by the invention shown in application drawing 3b
Structure block diagram, as shown in figure 8, the difference of monitoring of pulse system shown in Fig. 8 and monitoring of pulse system shown in Fig. 7 is: Fig. 8 institute
The monitoring of pulse system shown further includes large database concept service platform 830.Wherein, terminal device 720 is further used for: will count
To user's body health status be sent to large database concept service platform;Large database concept service platform 830 and terminal device 720 with
The mode of wire communication or wireless communication is connected, for receiving and storing the user's body health status of the transmission of terminal device 720,
User's body health status in the user's body health status received and large database concept service platform is subjected to analysis comparison,
Obtain customer analysis information, and customer analysis information be sent to terminal device 720, for 720 side of terminal device doctor and/
Or guardian checks or refers to, and doctor and/or guardian is enabled more in depth to understand the physical condition of user.It should
System realizes the real-time accurate monitoring for the user's physiologic information for having the pulse monitoring device to wearing, and makes to be in strange land
Guardian also can physical condition to user is accurate, timely grasps, so that guardian is more securely worked, is learnt.
Wherein, user's body health status includes the health status of heart, liver and gallbladder, kidney, lung, taste etc..
In addition, monitoring of pulse system provided by the present invention can not also include terminal device 720, and only include big data
Library service platform 830, then, it is obtained first by the central control module 333 in pulse monitoring device 710 according to analytical calculation
User's physiologic information count, user's body health status is obtained, then again by radio receiving transmitting module 338 by user's body
Body health status is sent to large database concept service platform 830, and large database concept service platform 830 is healthy by the user's body received
User's body health status in situation and large database concept service platform 830 carries out analysis comparison, obtains customer analysis information, most
Customer analysis information is sent to central control module 333 by radio receiving transmitting module 338 afterwards, to make central control module
333 control display modules 334 show customer analysis information, so that doctor and/or guardian check or refer to so that doctor and/
Or guardian can more in depth understand physical condition.
In addition, pulse monitoring device 710 is counted with terminal device 720 or with big in above-mentioned all monitoring of pulse systems
It can not only be connected through wireless communication according to the connection type of library service platform 830, can also directly pass through wire communication
Mode be connected, using wire communication mode be connected when, corresponding wireless telecom equipment can be saved, for example, pulse supervise
Survey the radio receiving transmitting module 338 in device 710.
In addition, user's body health status in the monitoring of pulse system provided in the above-described embodiments can according to
Family physiologic information is counted to obtain, and specifically, can compare pulse wave feature, to judge that the current body of user is strong
Health situation is diagnosed to be the disease of user in time.
Pulse monitoring device provided by the invention and system monitor the beat pulse of user by monitoring of pulse sensor,
It is physiology signal that the beat pulse of user, which is directly acted on the pressure conversion on monitoring of pulse sensor, real-time and accurately
The current physical condition of user is reflected, is diagnosed to be the disease of user in time, extraneous interference is avoided, improves prison
The accuracy and reliability of survey.In addition, the Human Physiology that can be exported from monitoring of pulse sensor by signal pre-processing module
Pulse signal is accurately extracted in signal, to analyze for the monitoring of subsequent pulse signal, can be effectively removed to pulse
The interference of monitoring further improves the accuracy and reliability of monitoring.In addition, pulse monitoring device provided by the invention and being
Not only accuracy and reliability is high for system, while also having structure and manufacture craft simple, low in cost, is suitble to large-scale industry raw
The advantages of production.Wherein, it does not need external power supply as monitoring of pulse sensor using triboelectricity component and is sensed to monitoring of pulse
Device is powered, and has greatly saved the energy, protects environment;And triboelectricity component matter is soft, light-weight, improves user
Comfort level when use.
Various modules mentioned in the present invention, circuit are by hard-wired circuit, for example, central control module can
To include microcontroller or microcontroller chip, analog-to-digital conversion module may include analog-digital converter etc..Although some of them module, electricity
Road is integrated with software, but the present invention it is claimed be the corresponding function of integrated software hardware circuit, rather than just software
Itself.
It should be appreciated by those skilled in the art that apparatus structure shown in attached drawing or embodiment is only schematical, table
Show logical construction.The module wherein shown as separation unit may be or may not be to be physically separated, as module
The component of display may be or may not be physical module.
Finally it should be noted that: the above enumerated are only specific embodiments of the present invention son, the technology of certain this field
Personnel can be modified to the present invention and modification, if these modifications and variations belong to the claims in the present invention and its equivalent skill
Within the scope of art, it is considered as protection scope of the present invention.
Claims (16)
1. a kind of monitoring of pulse sensor characterized by comprising triboelectricity component and for encapsulating the triboelectricity portion
The first encapsulated layer and the second encapsulated layer of part;
The triboelectricity component is used for the pressure conversion that the beat pulse of user acts on the triboelectricity component
Physiology signal output;Wherein, the triboelectricity component includes: that the first friction component being cascading and second rub
Brush assembly;First friction component includes the first electrode layer being stacked and the first high polymer insulating layer, described
Second friction component includes the second electrode lay;
First encapsulated layer is arranged on surface of the first electrode layer far from first high polymer insulating layer;
Second encapsulated layer is arranged on surface of the second electrode lay far from first friction component and described rubs
On the side surface for wiping electrical generation components;Second encapsulated layer with the first concave-convex array is provided on the surface of user's skin contact
Structure.
2. monitoring of pulse sensor according to claim 1, which is characterized in that the first concave-convex array structure include with
Flowering structure it is one or more: the bulge-structure of preset shape, the sunk structure of preset shape, banded structure, dermatoglyph shape
Striped, nanowire structure, nanocrystalline structure, nanorod structure and nano tube structure.
3. monitoring of pulse sensor according to claim 1 or 2, which is characterized in that the triboelectricity component is three layers
Structure, four-layer structure, five layers membrane structure or five layers of intervening electrode structure, the triboelectricity component include at least composition between two parties
Two opposite faces of frictional interface, the triboelectricity component have signal output end.
4. a kind of preparation method of monitoring of pulse sensor as described in any one of claims 1-3 characterized by comprising
Production first electrode layer and the first high polymer insulating layer are stacked gradually on the first encapsulated layer, obtain the first friction
Component;
The second electrode lay is made, the second friction component is obtained;
Together with first friction component is stacked with second friction component, triboelectricity component is obtained, wherein
Frictional interface is formed between first friction component and second friction component;
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of the triboelectricity component, and
The second encapsulated layer is made on the side surface of the triboelectricity component, obtains monitoring of pulse sensor.
5. the preparation method of monitoring of pulse sensor according to claim 4, which is characterized in that described to be sent out in the friction
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of electrical components, and in the triboelectricity portion
The second encapsulated layer is made on the side surface of part, obtaining monitoring of pulse sensor further comprises:
Obtain the template that a side surface is previously provided with the first concave-convex array structure;
The second encapsulated layer is made on surface of the template far from the first concave-convex array structure by spin coating proceeding;
The triboelectricity component is arranged on second encapsulated layer, the triboelectricity component is made to be provided with second electrode
One side surface of layer is in contact with second encapsulated layer, and encapsulates the side surface of the triboelectricity component and described second
Layer is in contact;
It is heating and curing to second encapsulated layer and cutting is handled, obtain monitoring of pulse sensor.
6. the preparation method of monitoring of pulse sensor according to claim 4, which is characterized in that described to be sent out in the friction
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of electrical components, and in the triboelectricity portion
The second encapsulated layer is made on the side surface of part, obtaining monitoring of pulse sensor further comprises:
Through spin coating proceeding on the second electrode lay of the triboelectricity component and on the side surface of the triboelectricity component
Make the second encapsulated layer, and be heating and curing to second encapsulated layer and cutting processing;
The concave-convex array structure of etching first, obtains monitoring of pulse sensor on second encapsulated layer.
7. a kind of preparation method of monitoring of pulse sensor as described in any one of claims 1-3 characterized by comprising
Stacking production first electrode layer and the first high polymer insulating layer, obtain the first friction component;
The second electrode lay is made, the second friction component is obtained;
Together with first friction component is stacked with second friction component, triboelectricity component is obtained, wherein
Frictional interface is formed between first friction component and second friction component;
The first encapsulated layer is made in the first electrode layer of the triboelectricity component;
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of the triboelectricity component, and
The second encapsulated layer is made on the side surface of the triboelectricity component, obtains monitoring of pulse sensor.
8. the preparation method of monitoring of pulse sensor according to claim 7, which is characterized in that described to be sent out in the friction
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of electrical components, and in the triboelectricity portion
The second encapsulated layer is made on the side surface of part, obtaining monitoring of pulse sensor further comprises:
Obtain the template that a side surface is previously provided with the first concave-convex array structure;
The second encapsulated layer is made on surface of the template far from the first concave-convex array structure by spin coating proceeding;
The triboelectricity component is arranged on second encapsulated layer, the triboelectricity component is made to be provided with second electrode
One side surface of layer is in contact with second encapsulated layer, and encapsulates the side surface of the triboelectricity component and described second
Layer is in contact;
It is heating and curing to second encapsulated layer and cutting is handled, obtain monitoring of pulse sensor.
9. the preparation method of monitoring of pulse sensor according to claim 7, which is characterized in that described to be sent out in the friction
Production is provided with the second encapsulated layer of the first concave-convex array structure on the second electrode lay of electrical components, and in the triboelectricity portion
The second encapsulated layer is made on the side surface of part, obtaining monitoring of pulse sensor further comprises:
Through spin coating proceeding on the second electrode lay of the triboelectricity component and on the side surface of the triboelectricity component
Make the second encapsulated layer, and be heating and curing to second encapsulated layer and cutting processing;
The concave-convex array structure of etching first, obtains monitoring of pulse sensor on second encapsulated layer.
10. a kind of pulse monitoring device characterized by comprising at least one pulse as described in any one of claims 1-3
Monitor sensor, monitoring ontology and governor circuit module;Wherein,
At least one monitoring of pulse sensor is set to the inside and/or surface of the monitoring ontology;
The governor circuit module is set to the internal or external of the monitoring ontology;The governor circuit module and at least one
Monitoring of pulse sensor is connected, for the physiology signal according at least one monitoring of pulse sensor output, analysis
The Pulse-Parameters for calculating user, obtain user's physiologic information.
11. pulse monitoring device according to claim 10, which is characterized in that the governor circuit module includes: signal
Preprocessing module, analog-to-digital conversion module, central control module, display module, interactive function module and power module;
The signal pre-processing module is connected at least one described monitoring of pulse sensor, for at least one described pulse
The physiology signal of monitoring sensor output is pre-processed, and pulse signal is obtained;
The analog-to-digital conversion module is connected with the signal pre-processing module, the mould for exporting the signal pre-processing module
Quasi- pulse signal is converted to the pulse signal of number;
The central control module is connected with the analog-to-digital conversion module, the number for being exported according to the analog-to-digital conversion module
Pulse signal, the Pulse-Parameters of analytical calculation user obtain user's physiologic information;
The display module is connected with the central control module, for showing user's physiology of the central control module output
Information;
The interactive function module is connected with the central control module, for sending user's interaction to the central control module
Instruction;
The power module is connected with the interactive function module, for providing electric energy.
12. pulse monitoring device according to claim 11, which is characterized in that the signal pre-processing module includes: electricity
Lotus amplification module, voltage amplification module and bandpass filtering modules block;
The charge amplification module is connected at least one described monitoring of pulse sensor, for supervising at least one described pulse
The physiology signal for surveying sensor output carries out impedance transformation;
The voltage amplification module is connected with the charge amplification module, and the human body for exporting the charge amplification module is raw
It manages signal and carries out voltage amplification;
The bandpass filtering modules block is connected with the voltage amplification module, and the human body for exporting to the voltage amplification module is raw
It manages signal and carries out bandpass filtering treatment, obtain pulse signal.
13. pulse monitoring device according to claim 11, which is characterized in that the governor circuit module further include: report
Alert module and/or radio receiving transmitting module and/or memory module;
The central control module is further used for: whether the Pulse-Parameters for the user that discriminatory analysis is calculated meet default arteries and veins
It fights parameter threshold, and controlling alarm electric signal is exported according to judging result;The alarm module and the central control module phase
Even, the controlling alarm electric signal for being exported according to the central control module carries out warning reminding;
The radio receiving transmitting module is connected with the central control module, and the user for exporting the central control module is raw
Reason information is sent to terminal device in a manner of wirelessly communicating;
The memory module is connected with the central control module, for storing described in the process of the central control module output
User's physiologic information that the pretreated pulse signal of signal pre-processing module and the central control module obtain.
14. a kind of monitoring of pulse system characterized by comprising such as the described in any item monitoring of pulse dresses of claim 10-13
It sets and terminal device;Wherein,
The terminal device is connected in a manner of wire communication or wireless communication with the pulse monitoring device, for receiving and depositing
User's physiologic information that the pulse monitoring device analytical calculation obtains is stored up, is carried out according to the user's physiologic information received
Statistics, obtains user's body health status, and/or send the control instruction for controlling the pulse monitoring device.
15. monitoring of pulse system according to claim 14, which is characterized in that the monitoring of pulse system further includes big number
According to library service platform;Wherein,
The terminal device is further used for: the user's body health status that statistics obtains is sent to the large database concept
Service platform;
The large database concept service platform is connected in a manner of wire communication or wireless communication with the terminal device, for receiving
And store the user's body health status that the terminal device is sent, by the user's body health status received with it is described
User's body health status in large database concept service platform carries out analysis comparison, obtains customer analysis information, and by the use
Family analysis information is sent to the terminal device.
16. a kind of monitoring of pulse system characterized by comprising such as the described in any item monitoring of pulse dresses of claim 10-13
It sets and large database concept service platform;Wherein,
The pulse monitoring device is further used for: being counted, is obtained according to user's physiologic information that analytical calculation obtains
To user's body health status;
The large database concept service platform is connected in a manner of wire communication or wireless communication with the pulse monitoring device, is used for
The user's body health status that the pulse monitoring device counts is received and stored, the user's body received is good for
User's body health status in health situation and the large database concept service platform carries out analysis comparison, obtains customer analysis letter
Breath, and the customer analysis information is sent to the pulse monitoring device.
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| CN201711338463.9A CN109662698A (en) | 2017-12-14 | 2017-12-14 | Monitoring of pulse sensor, preparation method, pulse monitoring device and system |
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