CN112674733A - Pulse feeling device - Google Patents

Abstract

An object of the present application is to provide a pulse feeling device, comprising: the first acquisition assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly; the second acquisition assembly comprises a second wrist positioning device, a second air bag, a fourth air bag and a second sensor assembly; and the information processing assembly is electrically connected with the first acquisition assembly and the second acquisition assembly respectively. Take first collection assembly as an example, the pulse feeling device accessible of this application first wrist positioner, first gasbag, third gasbag combined action will first sensor subassembly location is to user's left hand radial surface to gather the produced stable left hand pulse signal of user's left hand radial surface or the most obvious left hand pulse signal, and then improve the degree of accuracy of pulse feeling.

Description

Pulse feeling device

Technical Field

The application relates to the field of pulse detection, in particular to a pulse feeling technology.

Background

The pulse diagnosis is performed by touching the pulse of different parts of the human body to examine the pulse condition changes, the pulse diagnosis time and the body position of the patient are clinically and mainly grasped, the fingering and the finger force of the doctor are light and heavy, the pulse time is only limited to that each side pulse beats for not less than 50 times, and the pulse diagnosis can be correctly performed only by knowing the change condition of the pulse condition of a healthy person.

In pulse diagnosis, the key step of effectively acquiring pulse signals is to find the acquisition position of the pulse signals.

Disclosure of Invention

It is an object of the present application to provide a pulse feeling device.

According to one aspect of the present application, there is provided a pulse feeling device comprising: a first acquisition assembly, wherein the first acquisition assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly, the first wrist positioning device is used for fixing or adjusting pulse taking postures of the left wrist of a user, and the first air bag and the third air bag position the first sensor assembly to the radial side surface of the left hand of the user in operation so as to acquire left hand pulse signals of the user through the first sensor assembly; a second acquisition assembly, wherein the second acquisition assembly comprises a second wrist positioning device, a second air bag, a fourth air bag and a second sensor assembly, the second wrist positioning device is used for fixing or adjusting the pulse taking posture of the right wrist of the user, and the second air bag and the fourth air bag position the second sensor assembly to the radial surface of the right hand of the user during operation so as to acquire a right pulse signal of the user through the second sensor assembly; and the information processing assembly is respectively and electrically connected with the first acquisition assembly and the second acquisition assembly so as to send control instructions to the first acquisition assembly and the second acquisition assembly and acquire the left-hand pulse signals of the user acquired by the first acquisition assembly and the right-hand pulse signals of the user acquired by the second acquisition assembly.

In some embodiments, the pulse feeling device further comprises a first air pump assembly, a second air pump assembly, the first air bag of the first acquisition assembly and the second air bag of the second acquisition assembly operate based on the first air pump assembly; the third air bag of the first acquisition assembly and the fourth air bag of the second acquisition assembly work based on the second air pump assembly; the information processing assembly is electrically connected with the first air pump assembly and the second air pump assembly respectively so as to send control instructions to the first air pump assembly and the second air pump assembly.

In some embodiments, the first air pump assembly is connected to the first air bag through a first air duct and connected to the second air bag through a second air duct, wherein the first air pump assembly is used for inflating the first air bag and the second air bag or releasing the first air bag and the second air bag, and during inflation of the first air pump assembly to the first air bag and the second air bag, the first air bag drives the first sensor assembly to move towards the radial surface direction of the left hand of the user, and the second air bag drives the second sensor assembly to move towards the radial surface direction of the right hand of the user; the information processing assembly is used for sending a first inflation instruction or a first release instruction to the first air pump assembly.

In some embodiments, the pulse feeling device further comprises an activation module electrically connected with the information processing assembly, and when the activation module is triggered, the information processing assembly sends a first inflation instruction to the first air pump assembly.

In some embodiments, the second air pump assembly is connected to the third balloon through a third airway tube and connected to the fourth balloon through a fourth airway tube, wherein the second air pump assembly is configured to inflate or release the third balloon and the fourth balloon, and during inflation of the second air pump assembly to the third balloon and the fourth balloon, the third balloon drives the first sensor assembly to be positioned on the radial surface of the left hand of the user, and the fourth balloon drives the second sensor assembly to be positioned on the radial surface of the right hand of the user; the information processing assembly is used for sending a first inflation stopping instruction to the first air pump assembly and sending a second inflation stopping instruction to the second air pump assembly when the first air bag and/or the second air bag meet a first pressurization stopping condition, wherein the first pressurization stopping condition comprises that the current pressure value of the first air bag and/or the second air bag reaches a corresponding target pressure value.

In some embodiments, the first balloon is provided with a first pressure sensor to acquire a current pressure value of the first balloon through the first pressure sensor; the second air bag is provided with a second pressure sensor so as to acquire the current pressure value of the second air bag through the second pressure sensor; the information processing assembly is electrically connected with the first pressure sensor and the second pressure sensor to acquire current pressure values of the first air bag and the second air bag, and when the current pressure values of the first air bag and/or the second air bag reach corresponding target pressure values in the process that the information processing assembly controls the first air pump assembly to inflate the first air bag and the second air bag, the information processing assembly controls the first air pump assembly to stop inflating the first air bag and the second air bag.

In some embodiments, the pulse feeling device further comprises a first emergency button and a second emergency button, the first emergency button and the second emergency button are respectively electrically connected with the information processing assembly, and when the first emergency button and/or the second emergency button are triggered, the information processing assembly sends a first release instruction to the first air pump assembly and sends a second release instruction to the second air pump assembly.

In some embodiments, the first capturing assembly further comprises a first airbag support, a first cinching member, the first airbag being disposed inboard of the first airbag support, the first airbag defining a first receiving cavity, the first cinching member being disposed within the first receiving cavity, the third airbag being disposed inboard of the first cinching member, the third airbag defining a third receiving cavity, the first sensor assembly being disposed within the third receiving cavity and being configured to receive a left wrist of the user; the subassembly is gathered to the second still includes second gasbag support, second tightener, the second gasbag set up in the inboard of second gasbag support, the second gasbag is formed with second holding cavity, the second tightener set up in the second holding cavity, the fourth gasbag set up in the inboard of second tightener, the third gasbag is formed with fourth holding cavity, set up in the fourth holding cavity the second sensor subassembly, and be used for the holding user's right hand wrist.

In some embodiments, the central axes of the first balloon stent, the first cinch member, and the first sensor assembly coincide, the upper and lower apices of the first cinch member respectively connect to the first balloon, and the apex of the first sensor assembly connects to the third balloon; the central axes of the second air bag bracket, the second tightening piece and the second sensor assembly are overlapped, the upper top point and the lower top point of the second tightening piece are respectively connected with the second air bag, and the top point of the second sensor assembly is connected with the fourth air bag.

In some embodiments, the first wrist positioning device comprises a first positioning handle bar for the user to hold with the left hand to fix the pulse taking pose of the user's left wrist; the second wrist positioning device comprises a second positioning hand rod, and the second positioning hand rod is held by the right hand of the user to fix the pulse feeling posture of the wrist of the right hand of the user.

In some embodiments, the pulse feeling device further comprises a second air pump assembly, the third air bag and the fourth air bag work based on the second air pump assembly, and the information processing assembly is further configured to send a second stop inflation instruction to the second air pump assembly when the left-hand pulse signal acquired by the first sensor assembly and/or the right-hand pulse signal acquired by the second sensor assembly meet a second stop inflation condition, wherein the second stop inflation condition includes that the information processing assembly acquires a stable left-hand pulse signal acquired by the first sensor assembly and/or a stable right-hand pulse signal acquired by the second sensor assembly.

In some embodiments, the first wrist positioning device further comprises a first rotating component, the first positioning handle is disposed on the first rotating component, the first rotating component is used for driving the first positioning handle to rotate, the information processing component is electrically connected with the first rotating component, and the information processing component is used for sending a first rotating instruction to the first rotating component according to the left-hand pulse signal of the user collected by the first sensor component so as to adjust the pulse feeling posture of the left wrist of the user through the first wrist positioning device; the second wrist positioning device further comprises a second rotating component, the second positioning hand rod is arranged on the second rotating component, the second rotating component is used for driving the second positioning hand rod to rotate, the information processing component is electrically connected with the second rotating component, and the information processing component is used for sending a second rotating instruction to the second rotating component according to the right-hand pulse signal of the user, which is acquired by the second sensor component, so that the pulse diagnosis posture of the right-hand wrist of the user can be adjusted through the second wrist positioning device.

In some embodiments, the first sensor assembly comprises a plurality of first sensor units circumferentially distributed with respect to a left wrist of a user, and the information processing assembly is electrically connected to each of the first sensor units to acquire a left-hand pulse signal of the user acquired by each of the first sensor units and send a first rotation instruction to the first rotating assembly according to the left-hand pulse signal of the user acquired by each of the first sensor units; the second sensor assembly comprises a plurality of second sensor units which are circumferentially distributed relative to the right wrist of the user, the information processing assembly is electrically connected with each second sensor unit so as to acquire the right-hand pulse signal of the user acquired by each second sensor unit, and a second rotation instruction is sent to the second rotation assembly according to the right-hand pulse signal of the user acquired by each second sensor unit.

In some embodiments, the information processing component acquires left-hand pulse signals acquired by the first sensor units, determines a left-hand pulse signal with the most obvious pulse signal in the acquired left-hand pulse signals, and sends a first rotation instruction to the first rotation component according to the position of the first sensor unit acquiring the most obvious left-hand pulse signal so as to position the first target sensor unit on the radial surface of the left hand of the user where the most obvious left-hand pulse signal can be acquired; the plurality of second sensor units comprise a second target sensor unit, the information processing assembly acquires the right-hand pulse signals acquired by the plurality of second sensor units, determines the most obvious right-hand pulse signal in the acquired right-hand pulse signals, and sends a second rotation instruction to the second rotation assembly according to the position of the second sensor unit acquiring the most obvious right-hand pulse signal, so that the second target sensor unit is positioned on the radial surface of the right hand of the user and the most obvious right-hand pulse signal can be acquired.

In some embodiments, the information processing component is further configured to send a second stop inflation instruction to a second air pump component when the left-hand pulse signal acquired by the first sensor component and/or the right-hand pulse signal acquired by the second sensor component satisfy a second stop inflation condition, where the second stop inflation condition includes that the acquisition position corresponding to the first target sensor unit in the first sensor component is a position where the most obvious left-hand pulse signal generated at the radial side surface of the left hand of the user can be acquired; the acquisition position corresponding to the second target sensor unit in the second sensor assembly is a position where the most obvious right-hand pulse signal generated on the radial surface of the right hand of the user can be acquired.

In some embodiments, the information processing component is further configured to: and sending a first release instruction and a second release instruction to the first air pump assembly and the second air pump assembly before sending the first rotation instruction and the second rotation instruction to the first rotating assembly and the second rotating assembly.

In some embodiments, the first bladder comprises a plurality of uniformly distributed first sub-bladder chambers that communicate therebetween; the second air bag comprises a plurality of uniformly distributed second sub-air bag chambers which are communicated with each other.

In some embodiments, the first collection assembly further comprises a first support for supporting a left arm of the user; the second collection assembly further comprises a second support portion for supporting a right arm of the user.

In some embodiments, the pulse feeling device comprises a host, the information processing component is arranged in the host; the pulse feeling device further comprises an input component and an output component, wherein the input component and the output component are respectively communicated with the information processing component.

According to another aspect of the present application, there is provided a pulse feeling device comprising: a first collecting assembly, wherein the first collecting assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly, the first wrist positioning device is used for fixing or adjusting the pulse taking posture of the wrist of the user, the first air bag and the third air bag are used for positioning the first sensor assembly to the radial side surface of the wrist of the user so as to collect pulse signals of the user through the first sensor assembly; and the information processing assembly is electrically connected with the first acquisition assembly so as to send a control instruction to the first acquisition assembly and acquire the pulse signal of the user acquired by the first acquisition assembly.

Compared with the prior art, first collection subassembly among the pulse feeling device of this application includes first wrist positioner, first gasbag, third gasbag, first sensor subassembly, through first wrist positioner, first gasbag, third gasbag will first sensor subassembly location is to user's left hand radial surface to gather the produced stable left hand pulse signal of user's left hand radial surface or the most obvious left hand pulse signal, and then improve the degree of accuracy of pulse feeling. Similarly, the second acquisition assembly in the pulse feeling device comprises a second wrist positioning device, a second air bag, a fourth air bag and a second sensor assembly, and the second sensor assembly is positioned on the radial surface of the right hand of the user through the second wrist positioning device, the second air bag and the fourth air bag so as to acquire a stable right-hand pulse signal or a most obvious right-hand pulse signal generated on the radial surface of the right hand of the user, thereby improving the pulse feeling accuracy.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:

fig. 1 shows one of the overall structural diagrams of a pulse feeling device according to an embodiment of the present application;

fig. 2 is a second schematic diagram illustrating an overall structure of a pulse feeling device according to an embodiment of the present application;

FIG. 3 illustrates a top view of a pulse feeling device according to an embodiment of the present application;

FIG. 4 illustrates one of the states of motion of the first sensor assembly in one embodiment of the present application;

FIG. 5 illustrates a second state of motion of the first sensor assembly in one embodiment of the present application;

FIG. 6 shows one of the schematic structural views of the first and third balloons in one embodiment of the present application;

FIG. 7 shows a second schematic structural view of the first and third balloons in an embodiment of the present application;

fig. 8 is a schematic diagram illustrating pulse feeling results according to an embodiment of the present application.

The same or similar reference numbers in the drawings identify the same or similar elements.

Reference numerals

10 first acquisition assembly

11 first wrist positioning device

111 first positioning handle

12 first air bag

121 first sub-airbag Chamber

13 third air bag

14 first sensor assembly

141 first sensor unit

15 first emergency button

16 first air bag holder

17 first tightening member

18 first support part

19 first air bag cartridge

20 second acquisition assembly

21 second wrist positioning device

211 second positioning handle

25 second emergency button

26 second balloon stent

28 second support part

29 second airbag cartridge

30 host

Detailed Description

The present application is described in further detail below with reference to the attached figures.

In the description of the present application, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "up," "down," "front," "back," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the indicated orientations and positional relationships based on the orientation or positional relationship shown in the drawings, and are used for convenience of description and simplicity of description only, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first," "second," etc. may explicitly or implicitly include one or more of the features. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, a first feature "on," "above," and "over" a second feature includes that the first feature is directly above and obliquely above the second feature, or simply means that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly above and diagonally above the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

In a typical configuration of the present application, the terminal, the device serving the network, and the trusted party each include one or more processors (e.g., Central Processing Units (CPUs)), input/output interfaces, network interfaces, and memory.

The Memory may include forms of volatile Memory, Random Access Memory (RAM), and/or non-volatile Memory in a computer-readable medium, such as Read Only Memory (ROM) or Flash Memory. Memory is an example of a computer-readable medium.

Computer-readable media, including both non-transitory and non-transitory, removable and non-removable media, may implement information storage by any method or technology. The information may be computer readable instructions, data structures, modules of a program, or other data. Examples of computer storage media include, but are not limited to, Phase-Change Memory (PCM), Programmable Random Access Memory (PRAM), Static Random Access Memory (SRAM), Dynamic Random Access Memory (DRAM), other types of Random Access Memory (RAM), Read-Only Memory (ROM), Electrically Erasable Programmable Read-Only Memory (Electrically-Erasable Programmable Read-Only Memory (EEPROM), Flash Memory (Flash Memory) or other Memory technology, Compact Disc Read-Only Memory (CD-ROM), Digital Versatile Disc (Digital Versatile Disc, DVD) or other optical storage, magnetic tape or other magnetic or non-magnetic storage devices, may be used to store information that may be accessed by the computing device.

The device referred to in this application includes, but is not limited to, a user device, a network device, or a device formed by integrating a user device and a network device through a network. The user equipment includes, but is not limited to, any mobile electronic product, such as a smart phone, a tablet computer, etc., capable of performing human-computer interaction with a user (e.g., human-computer interaction through a touch panel), and the mobile electronic product may employ any operating system, such as an Android operating system, an iOS operating system, etc. The network Device includes an electronic Device capable of automatically performing numerical calculation and information processing according to a preset or stored instruction, and the hardware includes, but is not limited to, a microprocessor, an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (PLD), a Field Programmable Gate Array (FPGA), a Digital Signal Processor (DSP), an embedded Device, and the like. The network device includes but is not limited to a computer, a network host, a single network server, a plurality of network server sets or a cloud of a plurality of servers; here, the Cloud is composed of a large number of computers or web servers based on Cloud Computing (Cloud Computing), which is a kind of distributed Computing, one virtual supercomputer consisting of a collection of loosely coupled computers. Including, but not limited to, the internet, a wide area Network, a metropolitan area Network, a local area Network, a VPN Network, a wireless Ad Hoc Network (Ad Hoc Network), etc. Preferably, the device may also be a program running on the user device, the network device, or a device formed by integrating the user device and the network device, the touch terminal, or the network device and the touch terminal through a network.

Of course, those skilled in the art will appreciate that the foregoing is by way of example only, and that other existing or future devices, which may be suitable for use in the present application, are also encompassed within the scope of the present application and are hereby incorporated by reference.

Referring to fig. 1 to 7, the present application provides a pulse feeling device, which comprises a first acquisition assembly 10, a second acquisition assembly 20 and an information processing assembly, wherein the first acquisition assembly 10 is used for acquiring a left-hand pulse signal of a user, and the second acquisition assembly 20 is used for acquiring a right-hand pulse signal of the user. The first collecting assembly 10 comprises a first wrist positioning device 11, a first air bag 12, a third air bag 13 and a first sensor assembly 14, wherein the first wrist positioning device 11 is used for fixing or adjusting the pulse taking posture of the left wrist of the user, and the first air bag 12 and the third air bag 13 position the first sensor assembly 14 to the radial side surface of the left hand of the user during operation so as to collect the left-hand pulse signals of the user through the first sensor assembly 14; the second collecting assembly 20 comprises a second wrist positioning device 21, a second air bag, a fourth air bag and a second sensor assembly, wherein the second wrist positioning device 21 is used for fixing or adjusting the pulse taking posture of the wrist of the right hand of the user, and the second air bag and the fourth air bag position the second sensor assembly to the radial side surface of the right hand of the user during operation so as to collect the pulse signal of the right hand of the user through the second sensor assembly; the information processing component is electrically connected with the first acquisition component 10 and the second acquisition component 20 respectively so as to send control instructions to the first acquisition component 10 and the second acquisition component 20 and acquire the left-hand pulse signals of the user acquired by the first acquisition component 10 and the right-hand pulse signals of the user acquired by the second acquisition component 20. Wherein the first collecting component 10 collects the left hand pulse signal of the user through the first sensor component 14; the second collecting assembly 20 collects the right-hand pulse signal of the user through the second sensor assembly. In some embodiments, as shown in fig. 1, 2 and 3, the pulse feeling device further comprises a first arm cylinder 19 and a second arm cylinder 29 for the convenience of the user and accommodating the components. For example, the first air bag 12, the third air bag 13 and the first sensor assembly 14 of the first acquisition assembly 10 are arranged in the first arm cylinder 19, and the second air bag, the fourth air bag and the second sensor assembly of the second acquisition assembly are arranged in the second arm cylinder 29. For example, when a user uses the pulse feeling device to perform pulse feeling, the user inserts the left arm into the first arm cylinder 19; a right hand arm is inserted into the second arm cylinder 29 to collect the left hand pulse signal and the right hand pulse signal of the user, respectively. The present embodiment provides a pulse feeling device with a double-cylinder structure for acquiring left-hand pulse signals and right-hand pulse signals of a user, and since the first acquisition assembly 10 and the second acquisition assembly 20 have similar structures, the following embodiments will be described mainly by taking the first acquisition assembly 10 as an example.

Specifically, the first wrist positioning device 11 is used to fix or adjust the pulse taking posture of the left wrist of the user. For example, the first collecting assembly 10 further includes the first arm cylinder 19, and the first wrist positioning device 11 is disposed on the front side of the first arm cylinder 19 (refer to fig. 1). In pulse taking, the user puts his left hand into the first arm cylinder 19 and holds the first wrist positioning device 11 with his left hand, and the user holds the first wrist positioning device 11 to fix his left wrist so that the first and third air bags 12, 13 position the first sensor assembly 14 to the radial side surface of his left hand to acquire the left hand pulse signals during operation. For example, after the pulse taking posture of the user's left wrist is fixed by the first wrist positioning device 11, the first air cell 12 is operated to drive the first sensor assembly 14 to move along the direction shown in fig. 4 toward the radial surface of the user's left wrist; the third air cell 13 is operative to position the first sensor assembly further closely adjacent the radial surface of the left hand of the user (as shown in fig. 5). In some embodiments, the first wrist positioning device 11 is fixedly disposed (e.g., fixedly disposed on a front side of the first arm cylinder 19). In other embodiments, the first wrist positioning device 11 is rotatably disposed (e.g., rotatably disposed at the front side of the first arm cylinder 19), and the rotation angle of the first wrist positioning device 11 is controlled by the information processing component to adjust the pulse taking posture of the left wrist of the user, so that the first and third air bags 12 and 13 position the first sensor assembly 14 at the radial side surface of the left hand of the user and collect the most obvious left-hand pulse signals, so as to generate the pulse taking information of the user according to the left-hand pulse signals and the right-hand pulse signals with the most obvious pulse signals.

The first and third balloons 12, 13 are operative to position the first sensor assembly 14 to the left radial surface of the user. In some embodiments, the first air bag 12 is formed with a first receiving cavity, the third air bag 13 is disposed in the first receiving cavity, the third air bag 13 is formed with a third receiving cavity for the user to insert into the left arm, and the first sensor assembly 14 is disposed in the third receiving cavity. In some embodiments, the first balloon 12 and the third balloon 13 drive the first sensor assembly 14 to position to the left radial surface of the user during inflation. In some embodiments, after the user holds the first wrist positioning device and fixes the left wrist, the information processing device controls the first air cell 12 to inflate to drive the first sensor element 14 to move toward the radial side surface of the user's left hand, and controls the third air cell 13 to inflate to further position the first sensor element 14 to the radial side surface of the user's left hand.

The first sensor assembly 12 and the second sensor assembly acquire pulse signals based on pulse beats on the radial surface of the wrist of the user. For example, the first sensor assembly 12 is at a certain distance from the radial surface of the left hand of the user in the initial state so that the user can insert into the left arm, the first air cell 11 drives the first sensor assembly 12 to move towards the radial surface of the left hand of the user during the inflation process, and the third air cell 13 further positions the first sensor assembly 14 at the radial surface of the left hand of the user during the operation so that the first sensor assembly 14 collects the left-hand pulse signals of the user based on the pulsation of the radial artery on the radial surface of the left hand of the user.

The information processing assembly is respectively electrically connected with the first acquisition assembly and the second acquisition assembly so as to send control instructions to the first acquisition assembly and the second acquisition assembly and acquire the left-hand pulse signals of the user acquired by the first acquisition assembly and the right-hand pulse signals of the user acquired by the second acquisition assembly. In some embodiments, the information processing component is configured to send control commands (e.g., a first inflation command, a first stop inflation command, a first rotation command, etc.) to the first and second acquisition components, and to acquire the left-hand pulse signals of the user acquired by the first acquisition component, the right-hand pulse signals of the user acquired by the second acquisition component (specifically, the information processing component is electrically connected with the first and second sensor components to acquire the left-hand pulse signals acquired by the first and second sensor components in the first acquisition component and the right-hand pulse signals acquired by the second sensor component in the second acquisition component), and to process related information, such as to acquire corresponding sensing information, store and process data, communicate with other devices, and the like, Send instructions, etc.

In some embodiments, the pulse feeling device further comprises a first air pump assembly, a second air pump assembly, the first air bag 12 of the first acquisition assembly and the second air bag of the second acquisition assembly operate based on the first air pump assembly; the third air bag 13 of the first acquisition assembly and the fourth air bag of the second acquisition assembly work based on the second air pump assembly; the information processing assembly is electrically connected with the first air pump assembly and the second air pump assembly respectively so as to send control instructions to the first air pump assembly and the second air pump assembly. In some embodiments, the first balloon 12, the second balloon and the third balloon, the fourth balloon are operated by different air pump assemblies. For example, the first balloon 12 is rapidly inflated by the first air pump assembly such that, in operation, the first balloon 12 rapidly drives the first sensor assembly 14 in a direction toward the radial surface of the user's left hand. The third air cell 13 is slowly inflated by the second air pump assembly to further position the first sensor assembly 14 via the third air cell 13 to the left radial surface of the user. In this embodiment, since the first balloon 12 and the second balloon are used to drive the first sensor assembly 14 and the second sensor assembly to move toward the radial surface of the left hand and the radial surface of the right hand of the user, the first balloon 12 and the second balloon can be inflated rapidly, but the third balloon 13 and the fourth balloon drive the first sensor assembly 14 and the second sensor assembly to push the radial surface of the left hand and the radial surface of the right hand of the user tightly, at this time, the left hand and the right hand pulse signals collected by the first sensor assembly 14 and the second sensor assembly need to be approached slowly, so that the information processing assembly can analyze the left hand pulse signals and the right hand pulse signals collected by the first sensor assembly 14 and the second sensor assembly (for example, the first sensor assembly includes a plurality of first sensor units, the information processing assembly needs to detect the left hand pulse signals which are most obvious among the left hand pulse signals collected by the plurality of first sensor units; for example, the information processing component sends a second inflation stopping instruction to the second air pump component when determining that the first sensor component can collect a stable left-hand pulse signal), so that the inflation process of the third air bag and the fourth air bag needs to be performed slowly.

In some embodiments, the first air pump assembly is connected to the first air cell 12 via a first air conduit and connected to the second air cell via a second air conduit, and the first air cell 12 and the second air cell are inflated or released by the first air pump assembly, wherein during inflation of the first air cell 12 and the second air cell, the first air cell 12 drives the first sensor assembly 14 to move in a direction toward a radial surface of a left hand of the user, and the second air cell drives the second sensor assembly to move in a direction toward a radial surface of a right hand of the user; the information processing assembly is used for sending a first inflation instruction or a first release instruction to the first air pump assembly. In some embodiments, the first air pump assembly includes solenoid valves such that the information processing assembly controls the first air pump assembly to inflate, stop inflating, release gas, etc. the first air bag 12, the second air bag. Of course, it should be understood by those skilled in the art that the specific examples of the operations of controlling the first and second air bags to inflate, stop inflating, release air, etc. by the solenoid valves are merely examples, and other existing or future components or assemblies may be suitable for use in the present application and are included herein by reference.

In some embodiments, the pulse feeling device further comprises an activation module electrically connected with the information processing assembly, and when the activation module is triggered, the information processing assembly sends a first inflation instruction to the first air pump assembly. In some embodiments, the pulse feeling device inflates the first air bag 12 and the second air bag through the first air pump assembly, so that the first air bag 12 drives the first sensor assembly 14 to move towards the left hand of the user around the side surface during inflation; so that the second air bag drives the second sensor assembly to move towards the radial surface of the right hand of the user during the inflation process. In some embodiments, the activation module includes, but is not limited to, an activation button or a voice recognition module. In some embodiments, the activation module is arranged on one side of the pulse feeling device, or on the first arm cylinder 19 or the second arm cylinder 29 of the pulse feeling device. For example, the activation module includes the activation button, when the user clicks the activation button, an activation pulse operation is triggered, and the information processing component controls the first air pump component to inflate the first air bag 12 and the second air bag. For another example, the starting module includes the voice recognition module, and the information processing module presets the voice command as "start pulse taking", and when the voice recognition module recognizes the voice message of "start pulse taking", the information processing module controls the first air pump assembly to inflate the first air bag 12 and the second air bag.

In some embodiments, the second air pump assembly is connected to the third balloon through a third airway tube and connected to the fourth balloon through a fourth airway tube, wherein the second air pump assembly is configured to inflate or release the third balloon and the fourth balloon, and during inflation of the second air pump assembly to the third balloon and the fourth balloon, the third balloon drives the first sensor assembly to be positioned on the radial surface of the left hand of the user, and the fourth balloon drives the second sensor assembly to be positioned on the radial surface of the right hand of the user; the information processing assembly is used for sending a first inflation stopping instruction to the first air pump assembly and sending a second inflation stopping instruction to the second air pump assembly when the first air bag and/or the second air bag meet a first pressurization stopping condition, wherein the first pressurization stopping condition comprises that the current pressure value of the first air bag and/or the second air bag reaches a corresponding target pressure value. In some embodiments, the second air pump assembly includes a solenoid valve, so that the information processing assembly controls the second air pump assembly to inflate, stop inflating, release air and the like the third air bag 13 and the fourth air bag. Of course, it should be understood by those skilled in the art that the specific examples of the operations of controlling the third and fourth air bags to inflate, stop inflating, release air, etc. by the solenoid valves are only examples, and other existing or future components or assemblies may be suitable for the present application and are included in the scope of the present application by reference. In some embodiments, when the third air cell drives the first sensor assembly to abut against the radial surface of the left hand of the user, the first sensor assembly collects a left-hand pulse signal of the user and provides the left-hand pulse signal to the information processing assembly so that the information processing assembly can analyze the left-hand pulse signal. In some embodiments, the current pressure of the first bladder comprises a pressure value generated inside the bladder as a result of the first bladder being inflated; the current pressure of the second bladder comprises a pressure value generated inside the bladder as a result of the second bladder being inflated. In some embodiments, the information processing component presets a target pressure value, and when it is detected that the current pressure value of the first air bag and/or the second air bag reaches the target pressure value, the information processing component sends a first inflation stopping instruction to the first air pump component. In other embodiments, different users correspond to different target pressure values, the information processing component obtains the target pressure value corresponding to the user, and when the current pressure value of the first air bag and/or the second air bag reaches the target pressure value corresponding to the user, the information processing component sends a first inflation stopping instruction to the first air pump component.

In some embodiments, the first balloon 12 is provided with a first pressure sensor to acquire a current pressure value of the first balloon 12 by the first pressure sensor; the second air bag is provided with a second pressure sensor so as to acquire the current pressure value of the second air bag through the second pressure sensor; the information processing assembly is electrically connected with the first pressure sensor and the second pressure sensor to acquire current pressure values of the first air bag and the second air bag, and when the current pressure values of the first air bag and/or the second air bag reach corresponding target pressure values in the process that the information processing assembly controls the first air pump assembly to inflate the first air bag and the second air bag, the information processing assembly controls the first air pump assembly to stop inflating the first air bag and the second air bag. In some embodiments, in order to obtain the current pressure values of the first airbag 12 and the second airbag in real time so as to automatically control and stop the inflation process of the first airbag 12 and the second airbag, a first pressure sensor is further connected to the first airbag 12, and a second pressure sensor is further connected to the second airbag. The current pressure value in the first air bag 12 is obtained through real-time detection of the first pressure sensor, the current pressure value in the second air bag is obtained through real-time detection of the second pressure sensor, and when the current pressure value of the first air bag 12 and/or the current pressure value of the second air bag reach the corresponding target pressure value in the process that the information processing assembly controls the first air pump assembly to inflate the first air bag 12 and the second air bag, the information processing assembly automatically controls the first air pump assembly to stop inflating the first air bag 12 and the second air bag. For example, in order to ensure the safety of the user sufficiently, the information processing module controls the first air pump module to stop inflating the first air bag 12 and the second air bag as long as one of the current pressure value and the target pressure value is reached. In other embodiments, when the current pressure values of the first and second air bags 12 and 12 reach the target pressure value, the information processing assembly controls the first air pump assembly to stop inflating the first and second air bags 12 and 12. In some embodiments, the target pressure values corresponding to different body types of users are different, for example, a user with a fat body is thicker, the target pressure value is larger, a user with a fat body is thinner, and the target pressure value is smaller. In some embodiments, the information processing component stores therein target pressure values corresponding to a plurality of user groups including, but not limited to, deep-seated users (e.g., a user group with a fat body), superficial-seated users (e.g., a user group with a thin body), and flat-seated users (e.g., a user group with a body type within a normal range). For example, for a deep pulse user, because the fat is relatively thick, a greater degree of pressure is required to acquire a pulse signal. For the superficial pulse users, because the fat is less, the pressing pressure degree is less, and the pulse signals can be acquired. For the pulse-calming user, the fat thickness of the user is within the normal range, so that the pulse signal can be acquired by normally pressing the user. In some embodiments, the user sets (e.g., through the input component of the pulse feeling device) his/her own personal information (e.g., the user's weight, height, etc.) in advance of pulse feeling, and the information processing component looks up the pressure value corresponding to the user from the target pressure value table in table 1 below according to the user's personal information, and uses the pressure value as the target pressure value of the user. In this embodiment, users of different body types correspond to different target pressure values, and in a pulse feeling process, when the information processing module detects that a current pressure value of the first air bag and/or the second air bag reaches a target pressure value corresponding to a target user group to which the user belongs, the information processing module controls the first air pump module to stop inflating the first air bag and the second air bag.

TABLE 1 target pressure value Table

In some embodiments, the pulse feeling device further comprises a first emergency button 15 and a second emergency button 25, the first emergency button 15 and the second emergency button 25 are electrically connected to the information processing component respectively, and when the first emergency button 15 and/or the second emergency button 25 is triggered, the information processing component sends a first release instruction to the first air pump assembly and sends a second release instruction to the second air pump assembly. In some embodiments, in order to ensure the safety of the pulse taking process, the first acquisition assembly 10 further comprises a first emergency button 15, the second acquisition assembly 20 further comprises a second emergency button 25, and the first emergency button 15 and the second emergency button 25 are used for emergency stop of the pulse taking operation of the pulse taking device. For example, if the user presses the first emergency button 15 or the second emergency button 25 during the process of positioning the first sensor assembly 14 on the radial surface of the user's left hand by the first balloon 12 and the third balloon 13, the first balloon 12, the second balloon, the third balloon 13, the fourth balloon, the first sensor assembly 14, and the second sensor assembly restore the initial state (for example, by releasing the gas in the first balloon 12, the second balloon, the third balloon 13, and the fourth balloon so that the first balloon 12, the second balloon, the third balloon 13, the fourth balloon, the first sensor assembly 14, and the second sensor assembly restore the initial state), so as to release the left and right arms of the user, thereby ensuring that the user can use the pulse taking device to take pulses, not being excessively pressed. In some embodiments, the first emergency button 15 is disposed on the top end of the first wrist positioning device 11, and the second emergency button is disposed on the top end of the second wrist positioning device, so as to facilitate the emergency stop operation for the user.

In some embodiments, the first capturing assembly further comprises a first airbag support 16, a first cinching member 17, the first airbag 12 being disposed inside the first airbag support 16, the first airbag forming a first receiving cavity, the first cinching member 17 being disposed inside the first receiving cavity, the third airbag 13 being disposed inside the first cinching member 17, the third airbag 13 forming a third receiving cavity, the first sensor assembly 14 being disposed in the third receiving cavity and being configured to receive the left wrist of the user; the subassembly is gathered to second still includes second gasbag support 26, second tightener, the second gasbag set up in the inboard of second gasbag support 26, the second gasbag is formed with second holding cavity, the second tightener set up in the second holding cavity, the fourth gasbag set up in the inboard of second tightener, the third gasbag is formed with a fourth holding cavity, set up in the fourth holding cavity the second sensor subassembly, and be used for the holding the right hand wrist of user. In some embodiments, as shown in fig. 6 and 7, the first acquisition assembly further comprises a first balloon stent 16, the first balloon 12 being secured by the first balloon stent 16, e.g., the first balloon 12 being disposed inside the first balloon stent 16. In some embodiments, the first balloon stent 16 is a ring-like structure. In some embodiments, the pulse feeling device further comprises a first arm cylinder 19, and the first balloon stent 16 is disposed inside the first arm cylinder 19. The second collecting assembly further includes a second airbag support 26, and the second airbag is disposed at an inner side of the second airbag support 26, where a structure of the second airbag support 26 is the same as or similar to that of the first airbag support 16, and details are not repeated here. In some embodiments, the first fastener 17 comprises an airbag sheet, such as a resin-based material. Of course, those skilled in the art will appreciate that the specific materials for the first fastener described above are merely exemplary, and that other now known or later developed retractable, tightenable materials, such as would be suitable for use in the present embodiments, are within the scope of the present application and are incorporated herein by reference. For example, when the first airbag 12 inflates, the first cinching member 17 is cinched under the action of the first airbag 12. In some embodiments, the first fastener 17 is a loop structure. In some embodiments, with continued reference to FIGS. 6 and 7, the third bladder 13 is disposed inside the first cinch member 17 and wraps outside the first sensor assembly 14. For example, the first balloon 12 is inflated to move the first sensor assembly 14 in a radial direction toward the user's left hand, while the first cinching member 17 is compressed and tightened, and the third balloon 13 is inflated to further position the first sensor assembly 14 in close proximity to the radial surface of the user's left hand.

In some embodiments, the central axes of the first balloon stent 16, the first cinch member 17, and the first sensor assembly 14 coincide, the upper apex and the lower apex of the first cinch member 17 are respectively connected to the first balloon 12, and the apex of the first sensor assembly 14 is connected to the third balloon 13; the central axes of the second airbag support 26, the second fastening member and the second sensor assembly coincide, the upper vertex and the lower vertex of the second fastening member are respectively connected with the second airbag, and the vertex of the second sensor assembly is connected with the fourth airbag. In some embodiments, with continued reference to FIG. 6, for example, the dashed lines formed by points a and b in FIG. 6 are the central axes of the first airbag support 16, the first cinching member 17, and the first sensor assembly, and the upper and lower vertices of the first cinching member 17 are respectively connected to the first airbag so as to enable the first sensor assembly 14 to move along the central axes. For example, the first balloon 12 may be inflated to drive the first sensor assembly 14 in a direction toward the radial surface of the user's left hand as shown in FIG. 4, while the first balloon 12 tightens the first tightening member 17 during inflation, and then the third balloon 13 is inflated to position the first sensor assembly 14 in close proximity to the radial surface of the user's left hand. In some embodiments, the first wrist positioning device 11 is used to fix or adjust the pulse taking posture of the left wrist of the user, so that after the pulse taking posture of the left wrist of the user is fixed or adjusted, the first sensor assembly 14 needs to move along a fixed track to position the first sensor assembly 14 to the target position, so as to acquire the left pulse signal with stable or most obvious signal. For example, when the first wrist positioning device 11 enables the first sensor assembly 14 to acquire the left-hand pulse signal with the most obvious pulse signal, the initial pulse taking posture of the left wrist of the user needs to be adjusted, and after the pulse taking posture of the left wrist of the user is adjusted by rotating the first wrist positioning device 11, the first sensor assembly 14 needs to follow the same motion track to be positioned at the position where the left-hand pulse signal with the most obvious pulse signal can be acquired. The acquisition of the right-hand pulse signal is the same as or similar to the acquisition of the left-hand pulse signal, and the details are not repeated herein.

In some embodiments, the first wrist positioning device 11 comprises a first positioning handle bar 111, the first positioning handle bar 111 being held by the left hand of the user to fix the pulse taking posture of the left wrist of the user; the second wrist positioning device comprises a second positioning hand rod, and the second positioning hand rod is held by the right hand of the user to fix the pulse feeling posture of the wrist of the right hand of the user. For example, as shown in fig. 1, the first collecting assembly 10 includes a first arm cylinder 19, the first positioning lever 111 is fixedly disposed on the front side of the first arm cylinder 19, and the second positioning lever 211 is fixedly disposed on the front side of the second arm cylinder 29. For example, the first positioning handle bar 11 is fixedly disposed at a certain inclination angle at the front side of the first arm cylinder 19, and the first air cell 12 and the third air cell 13 drive the left radial side surface of the user where the first sensor assembly 14 is positioned during operation, so as to collect left-hand pulse signals through the first sensor assembly 14.

In some embodiments, the pulse feeling device further comprises a second air pump assembly, the third air bag 13 and the fourth air bag operate based on the second air pump assembly, and the information processing assembly is further configured to send a second stop inflation instruction to the second air pump assembly when the left-hand pulse signal acquired by the first sensor assembly 14 and/or the right-hand pulse signal acquired by the second sensor assembly satisfy a second stop inflation condition, where the second stop inflation condition includes that the information processing assembly acquires a stable left-hand pulse signal acquired by the first sensor assembly 14 and/or a stable right-hand pulse signal acquired by the second sensor assembly. In some embodiments, the condition that the second air pump assembly starts to inflate the third and fourth air bags is that the current pressure value of the first and/or second air bag reaches the corresponding target pressure value, and at this time, the information processing assembly controls the second air pump assembly to inflate the third and fourth air bags. In some embodiments, when the first positioning hand lever and the second positioning hand lever are fixedly arranged, the second stop inflation condition for the second air pump assembly to stop inflating the third air bag and the fourth air bag is that the information processing assembly can acquire a stable left-hand pulse signal and a stable right-hand pulse signal (for example, can continuously acquire the left-hand pulse signal and the right-hand pulse signal so as to form a pulse chart as shown in fig. 8), and at this time, the information processing assembly controls the second air pump assembly to stop inflating the third air bag 13 and the fourth air bag so as to analyze and process the left-hand pulse signal and the right-hand pulse signal acquired by the first sensor assembly 14 and the second sensor assembly.

In other embodiments, the first wrist positioning device 11 further includes a first rotating component in addition to the first positioning handle bar 111, the first positioning handle bar 111 is disposed on the first rotating component, the first positioning handle bar is disposed on the first rotating component, the first rotating component is configured to drive the first positioning handle bar to rotate, the information processing component is electrically connected to the first rotating component, the information processing component is configured to send a first rotating instruction to the first rotating component according to the left-hand pulse signal of the user collected by the first sensor component, so as to adjust the pulse taking posture of the left wrist of the user through the first wrist positioning device; the second wrist positioning device 21 further includes a second rotating component in addition to the second positioning handle bar 211, the second positioning handle bar is disposed on the second rotating component, the second rotating component is configured to drive the second positioning handle bar to rotate, the information processing component is electrically connected to the second rotating component, and the information processing component is configured to send a second rotation instruction to the second rotating component according to the right-hand pulse signal of the user collected by the second sensor component, so as to adjust the pulse taking posture of the right-hand wrist of the user through the second wrist positioning device. In this embodiment, in order to position the first sensor assembly 14 to a position where it can be used to collect the most significant left-hand pulse signals, the first wrist positioning device 11 can be rotated to adjust the pulse taking posture of the user's left wrist by rotation (for example, the first positioning rod is inclined at different angles, and the radial surface of the first positioning rod is rotated when the user holds the first positioning rod), so as to position the first sensor assembly 14 at the radial surface of the user's left wrist where it can be used to collect the most significant left-hand pulse signals. Taking the first rotating component as an example, the first rotating component includes but is not limited to a rotating motor, the rotating motor provides a driving force required for rotating the first positioning handle 111, the information processing component sends a first rotating instruction to the first rotating component (for example, the first rotating instruction includes rotating the first positioning handle to a left angle or rotating the first positioning handle to a right angle) to control the first positioning handle to rotate to a left angle or rotate to a right angle, and when the user holds the first positioning handle with the left hand, the first and third air bags 12 and 13 position the first sensor component 14 to a position where the most obvious left-hand pulse signal can be collected on the radial side surface of the left wrist of the user. In some embodiments, the first rotating assembly includes a plurality of rotational steps, wherein each rotational step corresponds to a unit rotational angle, and the first rotation command includes a left rotation by a certain rotational step or a right rotation by a certain rotational step. Of course, it should be understood by those skilled in the art that the specific components described above for controlling the first rotating assembly to drive the first positioning handle to rotate to the left or to rotate to the right by a certain angle through the information processing assembly are only examples, and other specific components that may be present or later come into existence are also included in the scope of the present application and are incorporated by reference herein. In some embodiments, the information processing component sends a first rotation instruction (e.g., left rotation or right rotation) to the first rotating component according to the left-hand pulse signal collected by the first sensor component 14 to position the first sensor component at a position on the radial side of the user's left wrist where the most obvious left-hand pulse signal can be collected, thereby improving the accuracy of pulse taking.

In some embodiments, the first sensor assembly 14 includes a plurality of first sensor units 141, the plurality of first sensor units 141 are circumferentially distributed with respect to the left wrist of the user, the information processing assembly is electrically connected to each of the first sensor units 141 to acquire the left-hand pulse signal of the user acquired by each of the first sensor units 141, and send a first rotation instruction to the first rotating assembly according to the left-hand pulse signal of the user acquired by each of the first sensor units 141; the second sensor assembly comprises a plurality of second sensor units which are circumferentially distributed relative to the right wrist of the user, the information processing assembly is electrically connected with each second sensor unit so as to acquire the right-hand pulse signal of the user acquired by each second sensor unit, and a second rotation instruction is sent to the second rotation assembly according to the right-hand pulse signal of the user acquired by each second sensor unit. In some embodiments, as shown in fig. 4, 5, the first sensor assembly comprises a plurality of first sensor elements 141, the plurality of first sensor elements 141 being circumferentially distributed with respect to the left wrist of the user. In some embodiments, the first balloon 12, when activated (e.g., inflated), drives the first sensor assembly 14 in the direction of the arrow shown in fig. 4 toward the radial surface of the user's left hand. In some embodiments, the first sensor unit 141 comprises a pulse sensor probe to acquire left-handed pulse signals of the user. In some embodiments, each of the first sensor units sends the left-hand pulse signal acquired by the first sensor unit to the information processing component, so that the information processing component determines a first rotation instruction sent to the first rotating component according to the left-hand pulse signal acquired by each of the first sensor units.

In some embodiments, the plurality of first sensor units 141 includes a first target sensor unit, the information processing component acquires the left-hand pulse signals acquired by the plurality of first sensor units 141, determines the left-hand pulse signal with the most obvious pulse signal among the acquired left-hand pulse signals, and sends a first rotation instruction to the first rotation component according to the position of the first sensor unit acquiring the most obvious left-hand pulse signal, so as to position the first target sensor unit on the radial surface of the left hand of the user where the most obvious left-hand pulse signal can be acquired; the plurality of second sensor units comprise a second target sensor unit, the information processing assembly acquires the right-hand pulse signals acquired by the plurality of second sensor units, determines the most obvious right-hand pulse signal in the acquired right-hand pulse signals, and sends a second rotation instruction to the second rotation assembly according to the position of the second sensor unit acquiring the most obvious right-hand pulse signal, so that the second target sensor unit is positioned on the radial surface of the right hand of the user and the most obvious right-hand pulse signal can be acquired. In some embodiments, the first target sensor unit comprises a high precision pulse sensor probe. For example, the information processing component acquires the left-hand pulse signals acquired by the plurality of first sensor units, and determines one of the left-hand pulse signals with the most obvious pulse signal (for example, referring to fig. 4, the left-hand pulse signal acquired by the labeled first sensor unit shown in fig. 4 is the most obvious, and the first sensor unit located in the middle position among the three first sensor units shown in fig. 4 is the first target sensor unit), so that the information processing component sends a signal to the first rotating component, rotates by a certain angle in the direction opposite to the direction in which the labeled first sensor unit is located, and positions the first target sensor unit to a position where the most obvious left-hand pulse signal can be acquired. For another example, in the three first sensor units shown in fig. 4, the first sensor unit located in the middle is the first target sensor unit, and the left-hand pulse signal acquired by the other first sensor unit opposite to the labeled first sensor unit is most obvious, the information processing component sends a signal to the first rotating component to rotate by a certain angle in a direction opposite to the direction in which the other first sensor unit is located, so as to position the first target sensor unit at a position where the most obvious left-hand pulse signal can be acquired. The left-hand pulse signals of the user are acquired through the first target sensor, and only the left-hand pulse signals acquired by the first target sensor are analyzed, so that the pulse feeling result is more accurate. Similarly, the second target sensor is used for acquiring the right-hand pulse signal of the user, and only the right-hand pulse signal acquired by the second target sensor is analyzed, so that the pulse feeling result is more accurate.

In some embodiments, the information processing component is further configured to send a second stop inflation instruction to a second air pump component when the left-hand pulse signal acquired by the first sensor component and/or the right-hand pulse signal acquired by the second sensor component satisfy a second stop inflation condition, where the second stop inflation condition includes that the acquisition position corresponding to the first target sensor unit in the first sensor component is a position where the most obvious left-hand pulse signal generated at the radial side surface of the left hand of the user can be acquired; the acquisition position corresponding to the second target sensor unit in the second sensor assembly is a position where the most obvious right-hand pulse signal generated on the radial surface of the right hand of the user can be acquired. When the first positioning hand lever and the second positioning hand lever are not fixedly arranged and can rotate under the driving of the first rotating assembly and the second rotating assembly respectively, the second air pump assembly stops inflating the third air bag and the fourth air bag under a second inflation stopping condition that the acquisition position corresponding to the first target sensor unit in the first sensor assembly is a position capable of acquiring the most obvious left-hand pulse signal generated on the radial side surface of the left hand of the user; the acquisition position corresponding to the second target sensor unit in the second sensor assembly is a position where the most obvious right-hand pulse signal generated on the radial surface of the right hand of the user can be acquired. It will be appreciated by those skilled in the art that the first sensor unit in the vicinity of the radial artery is also capable of acquiring pulse signals in general, but that the pulse signals vary with distance from the radial artery, e.g. if the first sensor unit is aimed directly at the radial artery, the left-handed pulse signals acquired by the first sensor unit are most evident. In order to align the first target sensor unit at the radial artery for analyzing the left-hand pulse signal acquired by the first target sensor unit, when the left-hand pulse signal acquired by the first target sensor unit is not the most obvious one of the left-hand pulse signals acquired by the plurality of first sensor units, the pulse feeling posture of the left-hand wrist of the user needs to be adjusted so that the first target sensor unit is aligned at a position where the most obvious left-hand pulse signal can be generated. The adjustment of the second target sensor unit is the same as or similar to the adjustment of the first target sensor unit, and is not repeated herein. In the embodiment, in order to enable the first target sensor unit in the first sensor assembly to acquire the position where the most obvious left-hand pulse signal can be generated on the radial surface of the left hand of the user, when the position is not acquired, a first rotating instruction is sent to the first rotating assembly, and a second rotating instruction is sent to the second rotating assembly; if so, the information processing component sends a second inflation stopping instruction to the second air pump component when the left-hand pulse signal and the right-hand pulse signal can be stably output.

In some embodiments, the information processing component is further configured to: and sending a first release instruction and a second release instruction to the first air pump assembly and the second air pump assembly before sending the first rotation instruction and the second rotation instruction to the first rotating assembly and the second rotating assembly. For example, the first sensor assembly 14 is positioned on the radial surface of the left hand of the user by the operation (e.g. inflation) of the first and third balloons 12, 13, and before the pulse taking state of the left wrist of the user is adjusted, the first and third balloons 12, 13 need to be deflated to release the left hand of the user so as to adjust the pulse taking posture of the left wrist of the user.

In some embodiments, the first airbag 12 includes a plurality of uniformly distributed first sub-airbag chambers 121, the plurality of first sub-airbag chambers 121 communicating therebetween; the second air bag comprises a plurality of uniformly distributed second sub-air bag chambers which are communicated with each other. In some embodiments, as shown in fig. 6 and 7, in order to make the first air cell 12 uniformly drive the first sensor assembly 14 to move toward the radial surface of the left hand of the user and make the second air cell uniformly drive the second sensor assembly to move toward the radial surface of the right hand of the user, the first air cell 12 includes a plurality of uniformly distributed first sub-air cell chambers 121, and the plurality of first sub-air cell chambers 121 are communicated with each other; similar to the first airbag 12, the second airbag also includes a plurality of uniformly distributed second sub-airbag chambers that communicate with one another.

In some embodiments, with continued reference to fig. 1 and 2, the first collection assembly further comprises a first support 18, the first support 18 for supporting a left arm of the user; the second acquisition assembly further comprises a second support 28, the second support 28 being for holding the right arm of the user. For example, when taking a pulse, the user puts the left arm on the first support 18 and the right arm on the second support 28, and the first support 18 and the second support 28 provide support for the left arm and the right arm of the user, so as to improve the pulse taking experience of the user.

In some embodiments, the pulse feeling device comprises a host 30, the information processing component is disposed in the host 30; the pulse feeling device further comprises an input component and an output component, wherein the input component and the output component are respectively communicated with the information processing component. In some embodiments, the first and second air pump assemblies are mounted within the main body 30. In some embodiments, the input component includes, but is not limited to, a keyboard, a microphone, and the like. In some embodiments, the output components include, but are not limited to, speakers, display screens, and the like. The input component and the output component are respectively communicated with the information processing component; optionally, the information processing component, the input component and the output component are all installed in the host 30, so that the user can input relevant information and obtain an output analysis result.

The above details the specific embodiment of the pulse feeling device comprising the first collecting assembly 10 and the second collecting assembly 20. Of course, in some embodiments, only one side collecting component is provided, and the collection of the pulse signals can also be realized. According to another aspect of the present application, there is also provided a pulse feeling device comprising: a first collecting assembly, wherein the first collecting assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly, the first wrist positioning device is used for fixing or adjusting the pulse taking posture of the wrist of the user, the first air bag and the third air bag are used for positioning the first sensor assembly to the radial side surface of the wrist of the user so as to collect pulse signals of the user through the first sensor assembly; and the information processing assembly is electrically connected with the first acquisition assembly so as to send a control instruction to the first acquisition assembly and acquire the pulse signal of the user acquired by the first acquisition assembly. The first collecting assembly comprises a first air pump assembly, a second air pump assembly, a first pressure sensor, a first emergency button, a first air bag bracket, a first tightening piece, a first supporting portion, a first arm cylinder and other components, and the structures and working modes of the first collecting assembly, the information processing assembly, the first wrist positioning device, the first air bag, the third air bag, the first sensor assembly, the first air pump assembly, the second air pump assembly and other components are the same as or similar to those of the first collecting assembly 10, the information processing assembly, the first wrist positioning device 11, the first air bag 12, the third air bag 13, the first sensor assembly 14, the first air pump assembly, the second air pump assembly and other components, and are not described in detail herein and are included herein by reference.

It will be evident to those skilled in the art that the present application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned. Furthermore, it is obvious that the word "comprising" does not exclude other elements or steps, and the singular does not exclude the plural. A plurality of units or means recited in the apparatus claims may also be implemented by one unit or means in software or hardware. The terms "first," "second," and the like are used to denote names, but not to denote any particular order.

Claims (20)

1. A pulse feeling device, wherein the pulse feeling device comprises:

a first acquisition assembly, wherein the first acquisition assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly, the first wrist positioning device is used for fixing or adjusting pulse taking postures of the left wrist of a user, and the first air bag and the third air bag position the first sensor assembly to the radial side surface of the left hand of the user in operation so as to acquire left hand pulse signals of the user through the first sensor assembly;

a second acquisition assembly, wherein the second acquisition assembly comprises a second wrist positioning device, a second air bag, a fourth air bag and a second sensor assembly, the second wrist positioning device is used for fixing or adjusting the pulse taking posture of the right wrist of the user, and the second air bag and the fourth air bag position the second sensor assembly to the radial surface of the right hand of the user during operation so as to acquire a right pulse signal of the user through the second sensor assembly;

and the number of the first and second groups,

the information processing assembly is respectively and electrically connected with the first acquisition assembly and the second acquisition assembly so as to send control instructions to the first acquisition assembly and the second acquisition assembly and acquire the left-hand pulse signals of the user acquired by the first acquisition assembly and the right-hand pulse signals of the user acquired by the second acquisition assembly.

2. The device of claim 1, wherein the pulse feeling device further comprises a first air pump assembly, a second air pump assembly, the first air bladder of the first acquisition assembly and the second air bladder of the second acquisition assembly operating based on the first air pump assembly;

the third air bag of the first acquisition assembly and the fourth air bag of the second acquisition assembly work based on the second air pump assembly;

the information processing assembly is electrically connected with the first air pump assembly and the second air pump assembly respectively so as to send control instructions to the first air pump assembly and the second air pump assembly.

3. The device according to claim 2, wherein the first air pump assembly is connected to the first balloon via a first air conduit and to the second balloon via a second air conduit, wherein the first air pump assembly is configured to inflate or release the first and second balloons, and wherein during inflation of the first air pump assembly to the first and second balloons, the first balloon drives the first sensor assembly to move in a direction toward a radial surface of a left hand of the user, and the second balloon drives the second sensor assembly to move in a direction toward a radial surface of a right hand of the user;

the information processing assembly is used for sending a first inflation instruction or a first release instruction to the first air pump assembly.

4. The device of claim 3, wherein the pulse feeling device further comprises an activation module electrically connected to the information processing assembly, the information processing assembly sending a first inflation command to the first air pump assembly when the activation module is triggered.

5. The apparatus according to claim 2, wherein the second air pump assembly is connected to the third balloon via a third airway and to the fourth balloon via a fourth airway, wherein the second air pump assembly is configured to inflate or release the third balloon and the fourth balloon, wherein during inflation of the third balloon and the fourth balloon by the second air pump assembly, the third balloon drives the first sensor assembly to be positioned on a radial surface of a left hand of the user and the fourth balloon drives the second sensor assembly to be positioned on a radial surface of a right hand of the user;

the information processing assembly is used for sending a first inflation stopping instruction to the first air pump assembly and sending a second inflation stopping instruction to the second air pump assembly when the first air bag and/or the second air bag meet a first pressurization stopping condition, wherein the first pressurization stopping condition comprises that the current pressure value of the first air bag and/or the second air bag reaches a corresponding target pressure value.

6. The device of claim 5, wherein the first balloon is provided with a first pressure sensor to acquire a current pressure value of the first balloon through the first pressure sensor;

the second air bag is provided with a second pressure sensor so as to acquire the current pressure value of the second air bag through the second pressure sensor;

the information processing assembly is electrically connected with the first pressure sensor and the second pressure sensor to acquire current pressure values of the first air bag and the second air bag, and when the current pressure values of the first air bag and/or the second air bag reach corresponding target pressure values in the process that the information processing assembly controls the first air pump assembly to inflate the first air bag and the second air bag, the information processing assembly controls the first air pump assembly to stop inflating the first air bag and the second air bag.

7. The device according to any one of claims 2 to 5, wherein the pulse feeling device further comprises a first emergency button and a second emergency button, the first emergency button and the second emergency button are respectively electrically connected with the information processing assembly, and when the first emergency button and/or the second emergency button are triggered, the information processing assembly sends a first release instruction to the first air pump assembly and sends a second release instruction to the second air pump assembly.

8. The apparatus of any one of claims 1 to 7,

the first acquisition assembly further comprises a first air bag bracket and a first tightening piece, the first air bag is arranged on the inner side of the first air bag bracket, a first accommodating cavity is formed in the first air bag, the first tightening piece is arranged in the first accommodating cavity, the third air bag is arranged on the inner side of the first tightening piece, a third accommodating cavity is formed in the third air bag, and the first sensor assembly is arranged in the third accommodating cavity and used for accommodating the left wrist of the user;

the subassembly is gathered to the second still includes second gasbag support, second tightener, the second gasbag set up in the inboard of second gasbag support, the second gasbag is formed with second holding cavity, the second tightener set up in the second holding cavity, the fourth gasbag set up in the inboard of second tightener, the third gasbag is formed with fourth holding cavity, set up in the fourth holding cavity the second sensor subassembly, and be used for the holding user's right hand wrist.

9. The apparatus of claim 8, wherein,

the central axes of the first air bag bracket, the first fastening piece and the first sensor assembly are coincident, the upper vertex and the lower vertex of the first fastening piece are respectively connected with the first air bag, and the vertex of the first sensor assembly is connected with the third air bag;

the central axes of the second air bag bracket, the second tightening piece and the second sensor assembly are overlapped, the upper top point and the lower top point of the second tightening piece are respectively connected with the second air bag, and the top point of the second sensor assembly is connected with the fourth air bag.

10. The device of claim 1, wherein the first wrist positioning device comprises a first positioning handle bar for the user to hold with the left hand to fix the pulse taking pose of the user's left wrist;

the second wrist positioning device comprises a second positioning hand rod, and the second positioning hand rod is held by the right hand of the user to fix the pulse feeling posture of the wrist of the right hand of the user.

11. The device of claim 10, wherein the pulse feeling device further comprises a second air pump assembly, the third air bag and the fourth air bag operate based on the second air pump assembly, and the information processing assembly is further configured to send a second stop inflation instruction to the second air pump assembly when the left-hand pulse signal collected by the first sensor assembly and/or the right-hand pulse signal collected by the second sensor assembly satisfy a second stop inflation condition, wherein the second stop inflation condition comprises the information processing assembly acquiring a stable left-hand pulse signal collected by the first sensor assembly and/or a stable right-hand pulse signal collected by the second sensor assembly.

12. The device according to claim 10, wherein the first wrist positioning device further comprises a first rotating component, the first positioning handle is disposed on the first rotating component, the first rotating component is used for driving the first positioning handle to rotate, the information processing component is electrically connected with the first rotating component, and the information processing component is used for sending a first rotating instruction to the first rotating component according to the left-hand pulse signal of the user collected by the first sensor component so as to adjust the pulse taking posture of the left wrist of the user through the first wrist positioning device;

the second wrist positioning device further comprises a second rotating component, the second positioning hand rod is arranged on the second rotating component, the second rotating component is used for driving the second positioning hand rod to rotate, the information processing component is electrically connected with the second rotating component, and the information processing component is used for sending a second rotating instruction to the second rotating component according to the right-hand pulse signal of the user, which is acquired by the second sensor component, so that the pulse diagnosis posture of the right-hand wrist of the user can be adjusted through the second wrist positioning device.

13. The device of claim 12, wherein the first sensor assembly comprises a plurality of first sensor units circumferentially distributed with respect to a left wrist of a user, the information processing assembly is electrically connected with each first sensor unit to acquire the left-hand pulse signal of the user acquired by each first sensor unit and send a first rotation instruction to the first rotating assembly according to the left-hand pulse signal of the user acquired by each first sensor unit;

the second sensor assembly comprises a plurality of second sensor units which are circumferentially distributed relative to the right wrist of the user, the information processing assembly is electrically connected with each second sensor unit so as to acquire the right-hand pulse signal of the user acquired by each second sensor unit, and a second rotation instruction is sent to the second rotation assembly according to the right-hand pulse signal of the user acquired by each second sensor unit.

14. The device according to claim 13, wherein the plurality of first sensor units include a first target sensor unit, the information processing component acquires the left-hand pulse signals acquired by the plurality of first sensor units, determines the left-hand pulse signal with the most obvious pulse signal in the acquired left-hand pulse signals, and sends a first rotation instruction to the first rotating component according to the position of the first sensor unit acquiring the most obvious left-hand pulse signal so as to position the first target sensor unit on the radial surface of the left hand of the user where the most obvious left-hand pulse signal can be acquired;

the plurality of second sensor units comprise a second target sensor unit, the information processing assembly acquires the right-hand pulse signals acquired by the plurality of second sensor units, determines the most obvious right-hand pulse signal in the acquired right-hand pulse signals, and sends a second rotation instruction to the second rotation assembly according to the position of the second sensor unit acquiring the most obvious right-hand pulse signal, so that the second target sensor unit is positioned on the radial surface of the right hand of the user and the most obvious right-hand pulse signal can be acquired.

15. The device of claim 14, wherein the information processing component is further configured to send a second stop inflation instruction to a second air pump component when the left-hand pulse signal collected by the first sensor component and/or the right-hand pulse signal collected by the second sensor component satisfy a second stop inflation condition, wherein the second stop inflation condition includes that the collection position corresponding to the first target sensor unit in the first sensor component is a position where the most obvious left-hand pulse signal generated at the radial side surface of the left hand of the user can be collected; the acquisition position corresponding to the second target sensor unit in the second sensor assembly is a position where the most obvious right-hand pulse signal generated on the radial surface of the right hand of the user can be acquired.

16. The apparatus of any of claims 12 to 15, wherein the information processing component is further to: and sending a first release instruction and a second release instruction to the first air pump assembly and the second air pump assembly before sending the first rotation instruction and the second rotation instruction to the first rotating assembly and the second rotating assembly.

17. The apparatus of any one of claims 1 to 16,

the first airbag comprises a plurality of uniformly distributed first sub-airbag chambers which are communicated with one another;

the second air bag comprises a plurality of uniformly distributed second sub-air bag chambers which are communicated with each other.

18. The apparatus of claim 1, wherein,

the first acquisition assembly further comprises a first supporting part for supporting the left arm of the user;

the second collection assembly further comprises a second support portion for supporting a right arm of the user.

19. The device of claim 1, wherein the pulse feeling device comprises a host, the information processing component being disposed within the host;

the pulse feeling device further comprises an input component and an output component, wherein the input component and the output component are respectively communicated with the information processing component.

20. A pulse feeling device, wherein the pulse feeling device comprises:

a first collecting assembly, wherein the first collecting assembly comprises a first wrist positioning device, a first air bag, a third air bag and a first sensor assembly, the first wrist positioning device is used for fixing or adjusting the pulse taking posture of the wrist of the user, the first air bag and the third air bag are used for positioning the first sensor assembly to the radial side surface of the wrist of the user so as to collect pulse signals of the user through the first sensor assembly;

and the number of the first and second groups,

and the information processing assembly is electrically connected with the first acquisition assembly so as to send a control instruction to the first acquisition assembly and acquire the pulse signal of the user acquired by the first acquisition assembly.

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