TW202042741A - Tcm pulse condition detection bracelet - Google Patents

Abstract

This disclosure is related to a TCM pulse condition detection bracelet which comprising a main body, a first belt body and a first pressure applying portion. The main body includes a touch screen, a starting module and a pulse detection main controller, the pulse detection main controller performs wireless connection with a remote TCM pulse condition server for transmitting relevant TCM pulse detection data. Furthermore, a plurality of piezoelectric elements and a plurality of deformation pushing elements are disposed in the first belt body, and the plurality of deformation pushing elements are disposed above the plurality of piezoelectric elements. When the starting module is activated, the plurality of deformation pushing elements are deformed, so that the plurality of piezoelectric elements are pressed downward. Meanwhile, the position and the action of the pressing of the piezoelectric elements are corresponding to different positions of the Radial Artery of the subject, and different blood pressure pulse changes are generated after being pressed. These blood pressure pulse changes are then converted into a plurality of electrical signals which are transmitted by the TCM pulse condition detection bracelet to the remote TCM pulse condition server.

Description

Pulse detection bracelet

The present invention relates to a pulse detection wristband, in particular to a convenient pulse detection wristband that can simulate the pulse detection by a Chinese physician and display the pulse result on the screen of the pulse detection wristband.

In the prior art, although there are patented technologies such as pulse diagnosis instrument system, pulse diagnosis instrument, pulse analysis device, pulse diagnosis measurement device and pulse measurement instrument, etc., most of these existing instruments cannot satisfy the user's desire to carry it with them. , Or the desire to be able to carry it conveniently when the user needs to take real-time pulse measurement. Therefore, it is necessary to provide a pulse detection bracelet that can be worn by the user to improve the shortcomings of the prior art.

The present invention discloses a pulse detection wristband. Aiming at the above-mentioned existing shortcomings, a wristband structure design capable of passing through a wearable device is proposed, and combined with the existing smart mobile device, it is convenient for users to wear with them, and can be used at any time. The user performs the pulse detection, which can simulate the pulse-related data and information that the Chinese doctor can obtain when the pulse is detected, and then compare, learn and store the data through the remote server, and then display it in the smart wear used by the user The installed screen, in this way, can simplify the operation and procedures of pulse detection in Chinese medicine, so that the user can perform pulse detection at any time.

The pulse detection wristband of the present invention is connected with a remote pulse status server, and the remote pulse status server is provided with a first look-up table. The pulse detection wristband includes: a main body, the The main body includes a touch screen, an activation module, and a pulse detection bracelet main controller. The touch screen and the activation module are electrically coupled to the pulse detection bracelet main controller. The main controller of the detection bracelet and the remote pulse server are wirelessly connected; at least one belt body, the at least one belt body is connected to one side of the main body, the at least one belt body is provided with a pressing part, the pressing The part is electrically coupled to the main controller of the pulse detection bracelet of the internal circuit of the main body; and inside the pressing part is provided: a first piezoelectric element electrically coupled to the pulse of the internal circuit of the main body Detect the main controller of the wristband, and contact the skin surface of the user's wrist to correspond to a position of the radial artery of the user's wrist; a first deformable depression element is arranged above the first piezoelectric element, and The activation module is electrically coupled to the internal circuit of the main body, the first deformable pressing element is connected to the first piezoelectric element; a second piezoelectric element is electrically coupled to the internal circuit of the main body The main controller of the pulse detection bracelet is parallel to the first piezoelectric element, and is in contact with the skin surface of the user's wrist to correspond to another position of the radial artery of the user's wrist; a second deformable pressing element , Located above the second piezoelectric element, and electrically connected to the activation module of the internal circuit of the main body, the second deformable pressing element and the second piezoelectric element are connected; a third piezoelectric element The element is electrically coupled to the main controller of the pulse detection bracelet of the internal circuit of the main body, and is arranged in parallel with the second piezoelectric element, and contacts the skin surface of the user's wrist to correspond to the radial artery of the user's wrist And a third deformable pressing element, located above the third piezoelectric element, and electrically connected to the activation module of the internal circuit of the main body, the third deforming pressing element and the first The three piezoelectric elements are connected; wherein the activation module activates the first to third deformable pressing elements to perform a first deformed pressing state, so that the first to third deformable pressing elements are individually deformed , Which in turn causes the first to third piezoelectric elements to be pressed down, and the pressing down action of the first to third piezoelectric elements corresponds to different positions of the user’s radial artery, and detects the user’s radial artery The different pulse changes generated after the different positions are compressed, the different pulse changes will return electrical signals to the main controller of the pulse detection bracelet, and then transmit to the remote pulse server compared to the first Check the contents of the table to obtain the pulse status of the user's radial artery.

In order to further understand the features and technical content of the present invention, please refer to the following detailed description and drawings about the present invention. However, the provided drawings are only for reference and description, and are not used to limit the present invention.

The invention discloses a pulse detection bracelet, which is a structural design of a smart bracelet used in wearable devices. It is combined with existing smart mobile devices and can be conveniently worn by users and can be used by users at any time Performing the pulse detection can not only simulate the pulse-related data and information that the Chinese medicine practitioner can obtain when the pulse is detected, but also can compare, learn and store the data through the remote server, and then display it on the user's intelligent type Wearable on the screen, this can simplify the operation and procedures of the Chinese medicine pulse detection, so that users can perform the operation of the Chinese medicine pulse at any time, and know what their current pulse status is at any time, effectively improving the user's health management function And efficiency.

In the following, referring to the accompanying drawings, various exemplary embodiments are described more fully, and some exemplary embodiments are shown in the accompanying drawings. However, the concept of the present invention may be embodied in many different forms, and should not be construed as being limited to the exemplary embodiments described herein. To be precise, the provision of these exemplary embodiments will make the present invention detailed and complete, and will fully convey the scope of the concept of the present invention to those skilled in the art. In the drawings, the size of the bracelet and related components and the relationship between the relative size and the connection can be exaggerated for clarity; in addition, similar numbers always indicate similar components.

It should be understood that although the terms above or below, left or right, etc. may be used in this text, these terms are used to clearly distinguish the position of a device from the relative position of the device, or to distinguish one field from another. The difference in position in the screen or the relative positional relationship between different fields is not used to limit the sequence relationship presented by the character serial number. Therefore, the left (front or upper) element discussed below can be referred to as the right (rear or lower) element without departing from the teaching of the concept of the present invention; and it does not necessarily have a literal or numerical continuity or sequence relationship; and, This article may use the term "plurality" or "multiple" to describe having multiple elements or fields, but these multiple elements or fields are not limited to two, three, or four and four. The number of elements or fields above one indicates the technology implemented. The above is explained first.

Referring to FIG. 1, an embodiment of the structure of the pulse detection bracelet of the present invention is shown. The pulse detection bracelet 10 is wirelessly connected to a remote pulse detection server 50. In practical applications, two The wireless connection between users can be Wi-Fi, Bluetooth, 4G or 5G communication.

Referring to Figure 2, the pulse detection bracelet 10 of the present invention includes a main body 11, a touch screen 12, a main control key 13, a first belt 14, a second belt 15, a first application The pressing portion 16, a second pressing portion 17, a first touch key 18 and a second touch key 19. Wherein, the main body 11 includes the touch screen 12, an activation module 43 (shown in FIG. 7) and a pulse detection bracelet main controller 40 (shown in FIG. 7), the touch screen 12 and The activation module 43 is electrically coupled to the main controller 40 of the pulse detection wristband, and the main controller 40 of the pulse detection wristband performs a wireless connection with the remote pulse server 50 to transmit related pulses. Detected data. In practice, the main controller 40 of the pulse detection bracelet can be a single-chip microprocessor MPU or a microcontroller MCU, or it can be a single chip that allows the designer to write a control program (Programmable). The chip controller is not limited by the present invention. The main control key 13 provided in the embodiment of FIG. 2 is electrically coupled to the main controller 40 of the pulse detection bracelet inside the main body 11, and serves as the main control button of the touch screen 12. This button can activate the Touch the screen 12 or turn off the touch screen 12. However, in another embodiment, the present invention may not be provided with the main control key 13, that is, the user directly uses the touch screen 12 to perform control actions, instead of executing through the button settings of the main control key 13. Control effect.

In addition, the first belt 14 is arranged on the right side of the main body 11, and the second belt 15 is arranged on the left side of the main body. The first pressure part 16 and the first touch key 18 are provided in the first belt body 14, and the second pressure part 17 and the second touch key 19 are provided in the second belt body 15. The first pressing portion 16 and the second pressing portion 17 are both electrically coupled to the main controller 40 of the pulse detection bracelet set inside the main body 11. At the same time, the first touch key 18 and the second The two touch keys 19 are also electrically coupled to the main controller 40 of the pulse detection bracelet, that is, the first pressing part 16 and the second pressing part can be operated through the control of the main controller 40 of the pulse detection bracelet 17 Perform the pressing operation. Fig. 3 is a backside schematic view of the pulse detection bracelet 10 of the present invention. The main body 11 shown is the bottom surface of the main body 11. Among them, the first pressing portion 16 on the back of the first strap 14 and the second The piezoelectric element provided by the present invention can be seen in the second pressing portion 17 on the back of the two straps 15. For further description, please refer to FIG. 4.

Referring to FIG. 4, a first piezoelectric element 21, a second piezoelectric element 22, and a third piezoelectric element 23 are provided in the first pressing portion 16, and a first deformable pressing element is correspondingly provided. 31. A second deformable pressing element 32 and a third deformable pressing element 33; that is, the first to third piezoelectric elements 21 to 23 and the corresponding first to third piezoelectric elements 21 to 23 are arranged inside the first belt 14 One to the third deformation pressing elements 31-33. The first piezoelectric element 21 is electrically coupled to the main controller 40 of the pulse detection bracelet in the internal circuit of the main body 11, and contacts the user's wrist skin surface 5 (shown in FIG. 5A) to correspond to the use A position of the wrist radial artery 3 (shown in Figure 6); the first deformable pressing element 31 is arranged above the first piezoelectric element 21, and the first deforming pressing element 31 is electrically coupled to the main body 11. In the activation module 43 (shown in FIG. 7) of the internal circuit, the first deformable pressing element 31 is connected to the first piezoelectric element 21, for example, as shown in FIG. 5A. The second piezoelectric element 22 is electrically coupled to the main controller 40 of the pulse detection bracelet in the internal circuit of the main body 11, and is parallel to the aforementioned first piezoelectric element 21, that is, the second piezoelectric element 22 and the first The piezoelectric elements 21 are arranged side by side to detect different positions of the radial artery 3 of the user, that is, contact with the skin surface 5 of the user's wrist and correspond to another position of the radial artery 3 of the user's wrist. The second deformable pressing element 32 is arranged above the second piezoelectric element 22 and is electrically connected to the activation module 43 of the internal circuit of the main body 11, and the second deformable pressing element 32 is connected to the second piezoelectric element. The piezoelectric element 22 is connected. Similarly, the third piezoelectric element 23 is electrically coupled to the main controller 40 of the pulse detection bracelet in the internal circuit of the main body 11, and is parallel to the second piezoelectric element 22, and is in contact with the user's wrist skin surface 5 And it corresponds to another position of the radial artery of the user's wrist. The third deformable pressing element 33 is disposed above the third piezoelectric element 23, and is also electrically connected to the activation module 43 of the internal circuit of the main body 11, and the third deformable pressing element 33 is the same as the third piezoelectric element 23 The two are connected. That is, the first to third piezoelectric elements 21 to 23 are arranged in a row, but the first to third piezoelectric elements 21 to 23 are arranged in a row. It can detect three different positions on the radial artery 3 on the wrist of the subject, and match the pulse control situation of different positions in the first look-up table and/or the second look-up table corresponding to different body parts. The pulse condition of the detective can further know whether the detected individual is healthy.

In practical application, the present invention can be provided with only the first to third piezoelectric elements 21-23 in the first pressing portion 16 in the first band 14, on the other hand, it can also be installed in the second band The fourth to sixth piezoelectric elements 24 to 26 are arranged in the second pressing portion 17 in 15 so that the pulse detection bracelet 10 can be conveniently worn on the left or right hand of the user, that is, pulse detection The wristband 10 can distinguish between different pulse conditions detected by the left hand or the right hand through the difference in the position of the different piezoelectric elements.

In FIG. 4, in the second pressing portion 17 of the second band 15 provided above the main body 11, a fourth piezoelectric element 24, a fifth piezoelectric element 25, and a sixth piezoelectric element are correspondingly provided 26. At the same time, a fourth deformable pressing element 34, a fifth deforming pressing element 35 and a sixth deforming pressing element 36 are correspondingly provided. The connection structure of the fourth to sixth piezoelectric elements 24 to 26 and the corresponding fourth to sixth deformation pressing elements 34 to 36 arranged inside the second band 15 is: the fourth piezoelectric element 24 The pulse detection bracelet main controller 40 is sexually coupled to the internal circuit of the main body 11, and is also in contact with the user's wrist skin surface 5 (shown in FIG. 5A), and corresponds to the user's wrist radial artery 3 ( Figure 6 shows) a position. The fourth deformable pressing element 34 is arranged above the fourth piezoelectric element 24, and the fourth deformable pressing element 34 is electrically coupled to the activation module 43 (shown in FIG. 7) of the internal circuit of the main body 11. And the fourth deformation pressing element 34 is connected to the fourth piezoelectric element 24, as shown in FIG. 5A, for example. The fifth piezoelectric element 25 is electrically coupled to the main controller 40 of the pulse detection wristband of the internal circuit of the main body 11, and is juxtaposed with the aforementioned fourth piezoelectric element 24. As shown in FIG. 4, the fifth piezoelectric element 25 and The fourth piezoelectric element 24 is arranged side by side to detect different positions of the radial artery 3 of the user, that is, contact with the skin surface 5 of the user's wrist and correspond to another position of the radial artery 3 of the user's wrist. The fifth deformation pressing element 35 is arranged above the fifth piezoelectric element 25 and is also electrically connected to the activation module 43 of the internal circuit of the main body 11, and the fifth deformation pressing element 35 is connected to the fifth piezoelectric element. The electric element 25 is connected. Similarly, the sixth piezoelectric element 26 is electrically coupled to the main controller 40 of the pulse detection bracelet of the internal circuit of the main body 11, and is arranged in parallel with the fourth and fifth piezoelectric elements 24, 25, and also with the user’s The wrist skin surface 5 contacts and corresponds to another position of the radial artery of the user's wrist. The sixth deformable pressing element 36 is disposed above the sixth piezoelectric element 26, and is also electrically connected to the activation module 43 of the internal circuit of the main body 11, and the sixth deformable pressing element 36 is the same as the sixth piezoelectric element 26 The two are connected. That is, the fourth to sixth piezoelectric elements 24 to 26 have a row arrangement structure. Similarly, the fourth to sixth piezoelectric elements 24 to 26 have a row arrangement structure. , Is to be able to detect three different positions on the radial artery 3 on the wrist of the detected person to match the pulse control situation of different body parts corresponding to different positions in the first look-up table and/or the second look-up table. It depends on the pulse condition of the detected person.

FIG. 5A is a schematic side view of the embodiment when the first deformable pressing element 31 of the present invention is not activated by the activation signal, but the first piezoelectric element 21 is not pressed. The first deformable pressing element 31 and the first piezoelectric element 21 are electrically connected to the main controller 40 of the pulse detection bracelet in the main body 11 by means of signal connection lines. However, in practice, the present invention also The first deformable pressing element 31 and the first piezoelectric element 21 can be electrically connected to the main controller 40 of the pulse detection bracelet through a flexible circuit board (FPCB), that is, the present invention is provided The first to sixth piezoelectric elements 21 to 26 and the corresponding first to sixth deformation pressing elements 31 to 36 are connected to the main controller 40 of the pulse detection bracelet. The electrical components 21 to 26 and the first to sixth deformable pressing components 31 to 36 are fabricated on the flexible circuit board, and then connected to the main controller 40 of the pulse detection bracelet. The first to sixth deformable lower pressure elements 31 to 36 of the present invention have two-stage lower pressure channels, which are respectively a light pressure and a heavy pressure pressure channel.

As shown in FIG. 5B, to show that the first deformed pressing element 31 is lightly pressed, the first piezoelectric element 21 is lightly pressed. In this lightly pressed state, the first piezoelectric element 21 is lightly pressed on the receiving side On the surface of the skin of a person’s wrist and corresponding to a position on the subject’s radial artery 3, at this time, after the radial artery 3 is lightly pressed by the first piezoelectric element 21, the first piezoelectric element 21 will detect the radial The blood pressure pulsation in the artery 3, and then the detected changes in the blood pressure pulsation are sent back to the main controller 40 of the pulse detection bracelet in the main body 11 for further interpretation and correspondence. The difference between the light pressing and heavy pressing performed by the first piezoelectric element 21 above is that the first deformation pressing element 31 has a different degree of deformation, that is, when pressing lightly, the first deforming pressing The deformation amount of the element 31 is relatively small. However, when the pressure is heavy, the deformation amount of the first deformation pressing element 31 is relatively large, as shown in FIG. 5C, that is, the deformation amount of the first deformation pressing element 31 in FIG. 5C is relatively large. The amount of deformation in FIG. 5B is large, so that the pressing operation of the first piezoelectric element 21 is heavy pressing. For further explanation, it can correspond to the different states of the first and second look-up tables disclosed in the first look-up table and the second look-up table, mainly corresponding to the first look-up table and the second look-up table For the column of the first deformation depression state, in this embodiment, the first deformation depression state of the present invention is light depression, and the second deformation depression state is heavy depression; conversely, the designer can also depress the first deformation The pressure state is changed to heavy pressure, and the second deformation depression state is light pressure.

Table I: First lookup The first pressure part (right hand) First deformation depression state The second deformation depression state First piezoelectric element Sanjiao Pericardium Second piezoelectric element stomach spleen Third piezoelectric element the large intestine lung

Table II: Second lookup table The second pressure part (left hand) First deformation depression state The second deformation depression state Fourth piezoelectric element bladder kidney Fifth piezoelectric element Guts liver Sixth piezoelectric element Small intestine heart

Figure 6 is a schematic diagram of the pulse detection wristband 10 of the present invention being worn on the wrist of a test subject, in which the fourth to sixth piezoelectric elements 24 to 26 of the second pressing portion 17 are pressed on the test subject In different positions on the radial artery of the wrist, the fourth to sixth piezoelectric elements 24 to 26 in these three different positions can correspond to the second look-up table shown in the second look-up table. Different body organs. Similarly, if it is worn on the right hand, the first to third piezoelectric elements 21 to 23 in the first pressing part 16 are pressed at different positions on the right hand radial artery 3, which corresponds to the first look-up table The state of different body organs presented in.

As shown in FIG. 7, the main components of the internal circuit of the pulse detection bracelet 10 of the present invention and the connection between the components are further disclosed. In the foregoing, the first to third piezoelectric elements 21-23 are The main controller 40 of the pulse detection bracelet is directly coupled; however, in another embodiment, the first to third piezoelectric elements 21-23 and the main controller 40 of the pulse detection bracelet are further It includes a micro signal amplifier 41 and a filter 42 connected. The input terminals of the micro-signal amplifier 41 are individually coupled to the first to third piezoelectric elements 21 to 23, and are used to detect the weak changes in the radial artery blood pressure detected by the first to third piezoelectric elements 21 to 23 The signal is amplified. The input of the filter 42 is coupled to the output of the micro signal amplifier 41 for filtering the amplified signal, and the output of the filter 42 is coupled to the input of the main controller 40 of the pulse detection bracelet Terminal for further control of the signal.

In another embodiment, the main controller 40 of the pulse detection bracelet includes a signal edge sampler 44, a sampled signal calculator 45, a personal data learning and recorder 46, and an update module 47. The input end of the signal edge sampler 44 is coupled to the filter 42, and its function is to perform a signal edge sampling action on the filtered signal. The input terminal of the sampled signal calculator 45 is coupled to the output terminal of the signal edge sampler 44, and its function is to calculate the sampled signal to obtain a set of values. The input terminal of the personal data learning and recorder 46 is coupled to the output terminal of the sampling signal calculator 45 for recording the obtained values and for learning personal data; and an update module is provided 47 is coupled to the personal data learning and recorder 46 to update the latest result of the user's pulse condition regularly or at any time. In actual operation, the signal edge sampler 44, the sampled signal calculator 45, the personal data learning and recorder 46, and the update module 47 are embedded in the circuit of the main controller 40 of the pulse detection bracelet It can also be implemented by firmware or software, and the present invention is not limited.

On the other hand, the aforementioned touch screen 12 and the main controller 40 of the pulse detection bracelet further include a real-time display unit 48 electrically coupled to the input terminal of the real-time display unit 48 to be coupled to the personal data learning The output end of the cum recorder 46 and the real-time display unit 48 are coupled to the touch screen 12. The function of the real-time display unit 48 is to perform the real-time pulse detection result when the update module 47 executes the user’s latest pulse detection result. It is immediately displayed on the touch screen 12 in the pulse detection bracelet 10.

In one embodiment, the activation action of the activation module 43 in FIG. 7 can be through the user's operation, sliding or clicking on the touch screen 12, and after pressing the touch screen 12, the activation will be activated. The module 13 drives the aforementioned first to sixth deformable pressing elements 31 to 36 to perform the difference between the first deformed pressing state (light pressing) or the second deformed pressing state (heavy pressing). In another embodiment, as shown in FIG. 2, a touch key is provided on at least one belt (for example, the first belt 14 and/or the second belt 15), for example, in FIG. There is a first touch key 18 and/or a second touch key 19. That is, the present invention can be used to provide only a single first touch key 18 to cooperate with the activation control function of the first pressing part 16 in the first belt body 14, or the first touch key 18 and The second touch key 19 allows the second touch key 19 to cooperate with the second pressing portion 17 in the second belt body 15 to perform a start control action. In addition, the first touch key 18 and/or the second touch key 19 are mainly electrically coupled to the main controller 40 of the pulse detection bracelet, and connected to the activation module 43, so, Therefore, the first touch key 18 and/or the second touch key 19 are linked with the activation module 43 in FIG. 7. When the user presses the first touch key 18 and/or the second touch key 19, the activation module 43 will be activated to drive the first to third deformable pressing elements 31 to 33 and/or the fourth ~ The sixth deformed depression element 34-36 performs the first deformed depression state (light depression) or the second deformed depression state (heavy depression).

In yet another embodiment, between the first to third deformation pressing elements 31 to 33 and the activation module 43 in FIG. 7, there is further included a deformation state setter 38 electrically coupled to the deformation state setter 38, wherein the deformation state is set The device 38 is coupled to the main controller 40 of the pulse detection bracelet through the connection relationship of the activation module 43. Such a technology can make the deformation state setter 38 and the first to third deformation The pressing elements 31-33 are coupled to have a linkage relationship. The main function is to set the first to third deformation depression elements 31 to 33 in addition to the first deformation depression state (light depression), but also a second deformation depression state (heavy depression). State of pressure.

Based on the above embodiments, the function of the activation module 43 in the present invention is to activate the first to third deformation pressing elements 31 to 33 and/or the fourth to sixth deformation pressing elements 34 to 36 to perform one In the first deformed depression state or the second deformed depression state, the first to third deformed depression elements 31 to 33 and/or the fourth to sixth deformed depression elements 34 to 36 are individually deformed, thereby causing The first to third piezoelectric elements 21 to 23 and/or the fourth to sixth piezoelectric elements 24 to 26 are pressed downward, and the first to third piezoelectric elements 21 to 23 and/or fourth to The depression actions of the sixth piezoelectric elements 24 to 26 correspond to the different positions of the user’s radial artery, and detect different blood pressure and pulse changes generated after the user’s radial artery is compressed at different positions. Different blood pressure pulse changes will send electrical signals back to the main controller 40 of the pulse detection bracelet, and then transmitted to the remote pulse server 50 compared to the first or second look-up table mentioned above. To get the pulse status of the user’s radial artery.

FIG. 7 also shows a schematic diagram of the connections formed by the internal circuit blocks of the remote pulse type server 50 in the pulse type detection bracelet 10 of the present invention, which includes a servo update unit 51, a comparison unit 52, a statistics unit 53, A learning unit 54 and a database 55. Wherein, the server update unit 51 is an end point for the remote pulse condition server 50 itself to perform wireless transmission/reception of data or an output/input port, which is when the user executes a new pulse condition detection , The internal data of the remote pulse server 50 can be updated, and the update action is a real-time update. The input terminal of the comparison unit 52 is coupled to the servo update unit 51, and compares the updated data with pre-stored data (for example, data with a preset health indicator value) to determine whether it is Healthy state. The input terminal of the statistics unit 53 is coupled to the comparison unit 52, and mainly collects statistics after the comparison. The input end of the learning unit 54 is coupled to the statistics unit 53 for learning the statistical data. The database 55 is coupled to the statistical unit 53 and the learning unit 54 at the same time. The function of the database 55 is to pre-store the pulse information-related data inside, that is, to store the first look-up table and the second look-up table. To correspond to the state of different parts of the body.

To sum up, in the present invention, a plurality of piezoelectric elements 21 to 26 and a plurality of deformation pressing elements 31 to 36 are provided in the first belt body 14, and the plurality of deformation pressing elements 31 to 36 are correspondingly provided in the plurality of piezoelectric elements 21 to 26. Above the piezoelectric elements 21~26. When the activation module 43 is activated, the plurality of deformation pressing elements 31 to 36 will be deformed, so that the plurality of piezoelectric elements 21 to 26 are pressed down, and the plurality of piezoelectric elements 21 to 26 are pressed down. The position and movement of the pressure will correspond to the different positions of the subject’s flexible artery 3 and produce different pulse changes after compression, and then convert these blood pressure pulse changes into electrical signals, which are transmitted by the pulse detection bracelet 10 To the remote pulse server 50. It effectively simplifies the operation and procedures of pulse detection in Chinese medicine, so that users can perform pulse detection in Chinese medicine at any time. Obviously, the technical content of the present invention has extremely strong patent application requirements.

However, the content described in the description of the present invention is only an example of a preferred embodiment. When it cannot be used to limit the scope of protection of the present invention, any relevant partial changes, minor modifications, amendments, or added technologies, or numerically Or changes in position, etc., still do not depart from the scope of protection of the present invention.

3: Radial artery 5: Wrist skin surface 10: Pulse detection bracelet 11: Main body 12: Touch screen 13: Main control key 14: First belt 15: Second belt 16: First pressure part 17: The second pressing section 18: the first touch key 19: the second touch key 21 to 26: the first to sixth piezoelectric elements 31 to 36: the first to sixth deformation pressing elements 38: the deformation state setter 40: Pulse detection bracelet main controller 41: Micro signal amplifier 42: Filter 43: Start module 44: Signal edge sampler 45: Sampling signal calculator 46: Personal data learning and recorder 47: Update module 48 : Real-time display unit 50: Remote pulse condition server 51: Servo update unit 52: Comparison unit 53: Statistics unit 54: Learning unit 55: Database

FIG. 1 is a schematic diagram of the overall architecture of an embodiment of the present invention;

Figure 2 is a schematic top view of an embodiment of the present invention;

Figure 3 is a schematic bottom view of an embodiment of the present invention;

4 is a schematic diagram of the internal structure of an embodiment of the present invention;

5A is a schematic diagram of the first piezoelectric element contacting the skin surface in an embodiment of the present invention;

5B is a schematic diagram of the first piezoelectric element lightly pressing the skin surface in the embodiment of the present invention;

5C is a schematic diagram of the first piezoelectric element pressing the skin surface in the embodiment of the present invention;

Fig. 6 is a schematic diagram of wearing an embodiment of the present invention;

FIG. 7 is a schematic diagram of circuit block connection according to an embodiment of the present invention.

10: Pulse detection bracelet

11: main body

12: Touch screen

13: Master key

14: The first belt

15: Second belt

16: The first pressure department

17: The second pressure department

18: The first touch button

19: Second touch key

Claims (10)

A pulse detection bracelet is connected to a remote pulse server. The remote pulse server is provided with a first look-up table. The pulse detection bracelet includes: a main body, the main body including a touch The screen, an activation module and a pulse detection bracelet main controller, the touch screen and the activation module are electrically coupled to the pulse detection bracelet main controller, the pulse detection bracelet main controller The device and the remote pulse server are wirelessly connected; at least one belt body, the at least one belt body is connected to one side of the main body, and the at least one belt body is provided with a pressure part which is connected to the internal circuit of the main body The main controller of the pulse detection bracelet is electrically coupled; and inside the pressing part is provided: a first piezoelectric element, which is electrically coupled to the main control of the pulse detection bracelet of the internal circuit of the main body The device is in contact with the skin surface of the user’s wrist and corresponds to a position of the radial artery of the user’s wrist; a first deformable depression element is provided above the first piezoelectric element and is electrically coupled to the In the activation module of the internal circuit of the main body, the first deformation pressing element is connected with the first piezoelectric element; a second piezoelectric element is electrically coupled to the pulse detection bracelet of the internal circuit of the main body The main controller is parallel to the first piezoelectric element, and is in contact with the user’s wrist skin surface to correspond to another position of the user’s wrist radial artery; a second deformable depression element is provided on the second Above the piezoelectric element and electrically connected to the activation module of the internal circuit of the main body, the second deformable pressing element is connected to the second piezoelectric element; a third piezoelectric element is electrically coupled The main controller of the pulse detection bracelet in the internal circuit of the main body is arranged in parallel with the second piezoelectric element, and is in contact with the skin surface of the user's wrist to correspond to another position of the radial artery of the user's wrist; and A third deformable pressing element is disposed above the third piezoelectric element and electrically connected to the activation module of the internal circuit of the main body. The third deformable pressing element is in phase with the third piezoelectric element. Wherein, the activation module is to activate the first to third deformable pressing elements to perform a first deformed pressing state, so that the first to third deformable pressing elements are individually deformed, thereby causing the first ~ The third piezoelectric element is pressed down, the pressing action of the first to third piezoelectric elements will correspond to different positions of the user’s radial artery, and after detecting the different positions of the user’s radial artery under pressure The generated different pulse changes, the different pulse changes will return electrical signals to the main controller of the pulse detection bracelet, and then transmitted to the remote pulse server to compare with the content of the first look-up table. Obtain the pulse status of the user's radial artery. The pulse detection bracelet according to claim 1, wherein the activation action of the activation module is through the user operating, sliding or clicking the touch screen, and after pressing the touch screen, the activation of the The activation module is used to drive the first to third deformable pressing elements to execute the first deformed pressing state. The pulse detection bracelet according to claim 1, wherein the at least one belt body is provided with a touch key, and the touch key is electrically coupled to the pulse detection bracelet main controller and is connected to the activation module Connection, so that the touch key and the activation module are linked; when the touch key is pressed, the activation module will be activated to drive the first to third deformation pressing components to perform the first deformation down压State. The pulse detection wristband according to claim 1, wherein the first to third deformable depression components not only perform the first deformed depression state, but also include a second deformable depression state; wherein, Compared with the second deformed depression state, the first deformed depression state is light depression, and the second deformed depression state is heavy depression. The pulse detection bracelet according to claim 1, wherein the first to third piezoelectric elements and the main controller of the pulse detection bracelet include: a micro signal amplifier, the input of the micro signal amplifier The terminal is coupled to the first to third piezoelectric elements for amplifying the signal of the weak changes in the radial artery blood pressure detected by the first to third piezoelectric elements; and a filter, The input terminal is coupled to the output terminal of the micro-signal amplifier for filtering the amplified signal, and the output terminal of the filter is coupled to the input terminal of the main controller of the pulse detection bracelet for signal processing Further control. The pulse detection wristband according to claim 5, wherein the main controller of the pulse detection wristband includes: a signal edge sampler, the input end of the signal edge sampler is coupled to the filter for connecting The filtered signal performs the sampling operation of the signal edge; a sampling signal calculator, the input end of the sampling signal calculator is coupled to the output end of the signal edge sampler for calculating the sampled signal, and then a A set of values; a personal data learning and recorder, the input end of the personal data learning and recorder is coupled to the output end of the sampling signal calculator, used to record the obtained values and to learn personal data; and An update module, coupled to the personal data learning and recorder, is used to update the latest results of the user's pulse detection regularly or at any time. The pulse detection bracelet of claim 1, wherein the touch screen and the main controller of the pulse detection bracelet further include a real-time display unit electrically coupled to the input terminal of the real-time display unit In the personal data learning and recorder, the output end of the real-time display unit is coupled to the touch screen, and the function of the real-time display unit is to perform real-time detection when the update module executes the user’s latest pulse detection result It is immediately displayed on the touch screen in the pulse detection bracelet. The pulse detection bracelet of claim 1, wherein the first to third deformation pressing components and the activation module further include a deformation state setter electrically coupled to the deformation state setter It is coupled to the main controller of the pulse detection bracelet through the activation module, so that the deformation state setter is coupled to the first to third deformation depression components to have a linkage relationship; its function is to set In addition to the first deformed depression state, the first to third deformable depression components are also set to a second deformed depression state. The pulse detection bracelet according to claim 1, wherein the remote pulse server includes: a server update unit, the server update unit is the remote end of the remote pulse server for external wireless transmission/reception of data After the user executes the new pulse detection, the internal data of the remote pulse server can be updated, and the update is real-time; a comparison unit, the input of the comparison unit is coupled to the server update unit , Is to compare the updated data with the pre-stored data; a statistical unit, the input of the statistical unit is coupled to the comparison unit, is to count the data after the comparison; a learning unit, the learning The input end of the unit is coupled to the statistical unit for learning the statistical data; and a database is coupled to the statistical unit and the learning unit at the same time; the pre-stored data is stored in the database , And the first lookup table is stored. The pulse detection wristband according to claim 1, wherein the pulse detection wristband further includes a second belt body connected to the other side of the main body, and the second belt body is provided There is a second pressing part, and the inside of the second pressing part is provided with: a fourth piezoelectric element, which is electrically coupled to the main controller of the pulse detection bracelet of the internal circuit of the main body, and is connected to the user's The wrist skin surface is in contact with a position corresponding to the radial artery of the user's wrist; a fourth deformable pressing element is arranged above the fourth piezoelectric element and is electrically coupled to the activation mode of the internal circuit of the main body Group, the two are connected; a fifth piezoelectric element, electrically coupled to the main controller of the pulse detection bracelet in the internal circuit of the main body, and parallel to the fourth piezoelectric element, and with the user’s The skin surface of the wrist is in contact with another position corresponding to the radial artery of the user's wrist; a fifth deformable pressing element is arranged above the fifth piezoelectric element and is electrically connected to the activation mode of the internal circuit of the main body Group; A sixth piezoelectric element, electrically coupled to the main controller of the pulse detection bracelet of the internal circuit of the main body, and parallel to the fifth piezoelectric element, and corresponding to the contact with the user's wrist skin surface To another position of the radial artery of the user's wrist; and a sixth deformable pressing element, which is arranged above the sixth piezoelectric element and is electrically connected to the activation module of the internal circuit of the main body.

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