CN111991028A - Cardiopulmonary sound auscultation detector with charger, auscultation system and control method - Google Patents

Abstract

The invention discloses a cardiopulmonary sound auscultation detector with a charger, which comprises a power supply module, a processor, a display screen, a storage and a signal transmission module, wherein the power supply module is respectively and electrically connected with the processor, the display screen and the signal transmission module, and is characterized in that: the detector is internally provided with a charger which is electrically connected with the power supply module and is used for charging the electronic stethoscope, and the charger is in signal connection with the processor. A auscultation system comprises an electronic stethoscope, an earphone and the detector, wherein a signal transmission module of the detector is in signal connection with the electronic stethoscope, and the earphone is in signal connection with the electronic stethoscope or/and the signal transmission module. A control method characterized by: the method comprises the following steps: when the electronic stethoscope is placed in the charger for charging, the charger sends a signal to the processor, and the processor closes the display screen of the detector.

Description

Cardiopulmonary sound auscultation detector with charger, auscultation system and control method

Technical Field

The invention relates to a stethoscope, in particular to a cardiopulmonary sound auscultation detector with a charger, an auscultation system and a control method.

Background

The stethoscope is a commonly used medical instrument and is mainly used for listening characteristic sounds of internal organs of a patient body in the clinical diagnosis process to judge the illness state. The stethoscope mainly picks up weak heart sound or breath sound signals through a sensitive sound pickup device, converts the weak heart sound or breath sound signals into electric signals, amplifies the electric signals and enables doctors to hear the sound in a diagnosed person through an earphone. Electronic stethoscopes, in particular wireless remote electronic stethoscopes, require power, are usually charged by a USB interface, wirelessly charged as in patent No. 201410250967.5, named wireless charging electronic stethoscopes device, and wirelessly charged as in patent No. 201721662561.3, named audio port charging circuit for electronic stethoscopes.

However, the stethoscope cannot ensure that the instrument automatically stops working when being charged, a user easily forgets to shut down the stethoscope when the stethoscope is not used, potential safety hazards of electricity utilization and information exist, and a computer with high cost needs to be equipped.

In order to overcome the defects, a cardiopulmonary sound auscultation detector with a charger, an auscultation system and a control method are developed.

Disclosure of Invention

The invention aims to provide a cardiopulmonary sound auscultation detector with a charger, an auscultation system and a control method, which effectively solve the problems that the traditional stethoscope is inconvenient to charge, cannot ensure that the instrument automatically stops working during charging, is easy to forget to shut down when a user stops using, has potential safety hazards of electricity utilization and information, and needs to be provided with a high-cost computer.

The technical scheme adopted by the invention to solve the technical problem is as follows: the utility model provides a take cardiopulmonary sound auscultation detector of charger, the detector includes power module, treater, display screen, accumulator, signal transmission module, and power module is connected its characterized in that with treater, display screen, signal transmission module electricity respectively: the detector is internally provided with a charger which is electrically connected with the power supply module and is used for charging the electronic stethoscope, and the charger is in signal connection with the processor.

The charger is provided with a containing cavity for containing the electronic stethoscope.

The charger is provided with a charging interface used for being connected with the electronic stethoscope in a charging mode.

The charger is also used for charging the earphone.

The detector is internally provided with a printer in signal connection with the processor.

An auscultation system, characterized by: the electronic stethoscope detector comprises an electronic stethoscope, an earphone and the detector, wherein a signal transmission module of the detector is in signal connection with the electronic stethoscope, and the earphone is in signal connection with the electronic stethoscope or/and the signal transmission module.

The signal transmission module is a wireless communication module, the electronic stethoscope and the earphone are wireless devices, the signal transmission module is in wireless communication connection with the electronic stethoscope, and the earphone is in wireless communication connection with the electronic stethoscope or/and the signal transmission module 5.

A control method characterized by: the method comprises the following steps:

when the electronic stethoscope is placed in the charger for charging, the charger sends a signal to the processor, and the processor closes the display screen of the detector.

When the electronic stethoscope is placed in the charger for charging, the processor controls the printer to print a report.

When the electronic stethoscope is taken out of the charger, the electronic stethoscope is automatically turned on.

When the earphone is taken out of the charger, the processor controls the signal transmission module of the detector to be in signal connection with the earphone, and the processor sends a signal to the display screen to prompt that the earphone is connected.

The invention has the beneficial effects that:

by adopting the technical scheme, the charger is in signal connection with the processor, the charger sends a signal to the processor when the electronic stethoscope is charged, and the processor closes the display screen of the detector, so that the detector automatically stops working, a user is not afraid of forgetting to shut down the electronic stethoscope, potential safety hazards of electricity utilization and information are eliminated, and the special detector also avoids high computer cost.

Therefore, the problems that the traditional stethoscope cannot be guaranteed to automatically stop working when being charged, a user forgets to shut down the stethoscope easily when stopping use, potential safety hazards of electricity utilization and information exist, and a computer with high cost needs to be equipped are effectively solved, and the stethoscope has the characteristics of simple structure, convenience in use, safety and durability.

Drawings

FIG. 1 is a wire frame diagram of the detector of the present invention.

FIG. 2 is a schematic view of the structure of the detector of the present invention.

Fig. 3 is a schematic structural diagram of the auscultation system of the present invention.

Fig. 4 is a schematic diagram of the control method related to the placement of the electronic stethoscope into the charger according to the present invention.

Fig. 5 is a schematic diagram of the control method of the present invention in connection with the removal of the electronic stethoscope from the charger.

Fig. 6 is a schematic diagram of the control method related to the placement of the earphone into the charger according to the present invention.

Detailed Description

Various embodiments of the present invention will be described more fully hereinafter. The invention is capable of various embodiments and of modifications and variations therein. However, it should be understood that: there is no intention to limit various embodiments of the invention to the specific embodiments disclosed herein, but on the contrary, the intention is to cover all modifications, equivalents, and/or alternatives falling within the spirit and scope of various embodiments of the invention.

Hereinafter, the terms "includes" or "may include" used in various embodiments of the present invention indicate the presence of the disclosed functions, operations, or elements, and do not limit the addition of one or more functions, operations, or elements. Furthermore, as used in various embodiments of the present invention, the terms "comprises," "comprising," "includes," "including," "has," "having" and their derivatives are intended to mean that the specified features, numbers, steps, operations, elements, components, or combinations of the foregoing, are only meant to indicate that a particular feature, number, step, operation, element, component, or combination of the foregoing, and should not be construed as first excluding the existence of, or adding to the possibility of, one or more other features, numbers, steps, operations, elements, components, or combinations of the foregoing.

Expressions (such as "first", "second", and the like) used in various embodiments of the present invention may modify various constituent elements in various embodiments, but may not limit the respective constituent elements. For example, the above description does not limit the order and/or importance of the elements described. The foregoing description is for the purpose of distinguishing one element from another. For example, the first user device and the second user device indicate different user devices, although both are user devices. For example, a first element could be termed a second element, and, similarly, a second element could be termed a first element, without departing from the scope of various embodiments of the present invention.

The terminology used in the various embodiments of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the various embodiments of the invention. Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which various embodiments of the present invention belong. The terms (such as those defined in commonly used dictionaries) should be interpreted as having a meaning that is consistent with their contextual meaning in the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein in various embodiments of the present invention.

As shown in fig. 1 and 2, a cardiopulmonary sound auscultation detector with a charger is shown, wherein the detector 100 comprises: power module 1, treater 2, display screen 3, accumulator 4, signal transmission module 5, power module 1 is connected with treater 2, display screen 3, signal transmission module 5 electricity respectively, the detector 100 is built-in to be connected with power module 1 electricity and is used for the charger 7 that charges for the electron stethoscope, charger 7 and 2 signal connection of treater. Through with charger and treater signal connection, charger send signal for the treater when charging for the electron stethoscope, the display screen 3 of detector 100 is closed to the treater to reach the detector automatic shutdown work, the user is afraid of forgetting the shutdown, gets rid of power consumption potential safety hazard and information potential safety hazard, and high computer cost is still avoided to dedicated detector. The charger can charge the electronic stethoscope in a wireless mode, a contact conduction mode or a plugging and unplugging mode through wired interfaces such as a USB interface and an audio interface.

The charger 7 is provided with a containing cavity 72 for containing the electronic stethoscope, so that the electronic stethoscope can be conveniently contained, the electronic stethoscope is further ensured to be placed at a charging position, and the electronic stethoscope can be prevented from slipping off.

The charger 7 is provided with a charging interface 71 for charging connection with the electronic stethoscope.

The charger 7 is also used for charging the headset.

The detector 100 is provided with a printer 6 connected with the processor 2 for printing reports.

Preferably, the charger 7 is located on top of the detector 100 to facilitate placement of the electronic stethoscope.

The memory 4 is internally provided with an operating system 41, a cardiopulmonary sound signal classification program 42 and a cardiopulmonary sound auscultation position identification program 43, and the memory 4 can also store cardiopulmonary sound signals to be classified and determined cardiopulmonary sound types obtained by conversion of the processor. Preferably, the storage 4 is a NandFlash storage.

The signal transmission module 5 is used for receiving the cardiopulmonary sound signals converted by the electronic stethoscope.

The processor 2 is configured to convert the cardiopulmonary sound signals received by the signal transmission module 5 and sent by the electronic stethoscope into cardiopulmonary sound signals to be classified, compare the cardiopulmonary sound signals to be classified with a signal classification model in the cardiopulmonary sound signal classification program 42 and determine a type, send the type and a waveform of the cardiopulmonary sound signals to be classified to the display screen 3, display the type on the display screen 3 in a text form, display the cardiopulmonary sounds to be classified in a waveform form, and display a report on the display screen 3, where the report content includes the type displayed in the text form and the cardiopulmonary sounds to be classified displayed in the waveform form.

Preferably, the display screen 3 is a touch display screen, and the processor 2 is further configured to identify a classified position in the cardiopulmonary sound auscultation position identification program 43 of a touched position of the display screen 3 representing a cardiopulmonary sound auscultation position, the touched position being displayed at a position located on a human body pattern displayed on the display screen 3. When the processor 2 receives a cardiopulmonary sound signal to be classified with a preset duration, the memory 4 stores the cardiopulmonary sound signal to be classified at the classification position. When the device is used, a doctor clicks a position needing auscultation on a human body pattern on the display screen 3, the position is a touch position, the processor 2 identifies a classification position of the touch position in the cardiopulmonary sound auscultation position identification program 43, at the moment, the doctor places the electronic stethoscope 200 at a body position corresponding to a patient to listen for a preset time, when the processor 2 receives a cardiopulmonary sound signal to be classified for a preset time, the storage 4 stores the cardiopulmonary sound signal to be classified at the classification position, the processor 2 compares the cardiopulmonary sound signal to be classified with a signal classification model in the cardiopulmonary sound signal classification program 42 to determine the type, the type and the waveform of the cardiopulmonary sound signal to be classified are sent to the display screen 3 to be displayed, and the doctor can look up the stored cardiopulmonary sound type and waveform to be classified at any time.

The heart sound auscultation determines the types of the heart sounds as follows: normal heart sound, sinus tachycardia, sinus bradycardia, incomplete closure of the two main valves, heart failure, one-sound low, mitral insufficiency, aortic stenosis, and pulmonary artery relative insufficiency. The type of lung sounds determined by auscultation of lung sounds is as follows: normal/bronchial/youth, respiratory rhythm/tidal breathing, respiratory rhythm/gradual cessation/cessation, abnormal alveolar/respiratory sound reinforcement, abnormal alveolar/intermittent, abnormal bronchial/lung tissue consolidation, wet/non-loud rough/wet rale.

The detector 100 is internally provided with an internal loudspeaker 8 electrically connected with the processor 2, preferably, the internal loudspeaker 8 is a high-fidelity loudspeaker, so that ears of a doctor are liberated, and the disease infection risk caused by wearing earphones or earphones is avoided.

Preferably, when the cardiopulmonary sound signal to be classified does not reach the preset time length, the processor sends an alarm signal to the display screen 3, and the display screen 3 displays an alarm. At the same time, the processor sends an alarm signal to the built-in speaker 8, and the built-in speaker 8 displays an alarm.

The display screen 3 is used for displaying the cardiopulmonary sound waveform, the signal classification model, the determined cardiopulmonary sound type, the touch position, the heart rate, the respiratory rate and other report contents, and inputting a control command to the processor. The user can issue a command for switching the cardiopulmonary sounds on the display screen 3. Preferably, the display screen 3 is a 10-inch touch TFT display screen.

The detector 100 is internally provided with a printer 6 which is in signal connection with the processor and is used for printing reports, and the operation is convenient and fast. Preferably, the printer 6 is a thermal printer.

The apparatus 100 is further provided with an identity information reader 10 electrically connected to the processor 2 for reading the patient identity information carrier in the information carrier. Preferably, the identity information reader is a two-dimensional code reader, and is used for decoding the two-dimensional code to obtain the patient identity information. The storage 4 stores patient identification information. The patient identity information includes name, medical history, blood type, age, gender, etc.

The electronic stethoscope 200 is internally provided with an action response device, when the electronic stethoscope 200 is picked up, the action response device senses action and sends a signal to the signal transmission module 5, the processor 2 starts a heart sound mode or a lung sound mode, and the display screen 3 displays a corresponding mode interface. Preferably, the motion-responsive device is a gravity sensor.

The detector 100 is provided with a charger 7 electrically connected to the power module 1 for charging the electronic stethoscope 200 and the earphone 300. The charger 7 is in signal connection with the processor 2, and when the electronic stethoscope 200 is placed in the charger 7 for charging, the processor 2 controls the printer 6 to print a report; when the electronic stethoscope 200 is removed from the charger 7, the electronic stethoscope 200 is automatically turned on. When the earphone 300 is taken out of the charger 7, the processor 2 controls the signal transmission module 5 of the detecting instrument 100 to be in signal connection with the earphone 300, and the processor 2 sends a signal to the display screen 3 to prompt that the earphone 300 is connected.

The detector 100 is provided with an operation key 9 in signal connection with the processor 2, and the operation key 9 can make commands to the processor 2, such as starting and closing the detector, printing a report, switching heart and lung sounds and adjusting volume.

Preferably, the monitor 100 displays a calendar while in standby.

The electronic stethoscope further comprises a disinfecting device 11 electrically connected with the power module 1, and the electronic stethoscope 200 is placed on the disinfecting device 11 for disinfection, so that auscultation can be performed under safe and sanitary conditions every time, and disease infection caused by auscultation is avoided.

Disinfection device 11 includes stock solution chamber 12 and the atomizing device 13 that is located stock solution chamber 12, pours the antiseptic solution into toward stock solution chamber 12 during the use, and atomizing device 13 can be with the antiseptic solution atomizing to disinfect to electronic stethoscope 200.

As shown in fig. 3, the bottom of the atomizing device 13 is connected to the liquid absorbing core rod 14 leading to the bottom of the liquid storage cavity 12, the atomizing device 13 is an ultrasonic atomizing device, and during use, the liquid absorbing core rod 14 absorbs the disinfectant to the atomizing device 13 for oscillation and atomization, so as to sufficiently sterilize the electronic stethoscope 200.

The disinfection device 11 further comprises an ultraviolet lamp 15 emitting light towards the diaphragm of the electronic stethoscope 200, so as to further disinfect the stethoscope.

The disinfection device 11 further comprises a limiting part 16 for accommodating the vibrating diaphragm of the electronic stethoscope 200, the liquid storage cavity 12 is located below the limiting part 16 in the surrounding range, the vibrating diaphragm can be accurately placed at the disinfection position, and the disinfection effect is guaranteed.

The limiting member 16 is a concave cavity, and can well accommodate the electronic stethoscope 200.

Preferably, the disinfection device further comprises an object sensing device 17 located at the disinfection device 11, and the processor 2 is in signal connection with the object sensing device 17 and the disinfection device 11. During the use, when electron stethoscope 200 was put on degassing unit 11, object perception device 17 perception after electron stethoscope 200 sent the signal for treater 2, treater 2 opened degassing unit 17 and disinfected, treater 2 closed display screen 3 simultaneously, and signal transmission module 5 also sends the shut-off signal and closes for electron stethoscope 200, finishes the auscultation. When the electronic stethoscope 200 is picked up, the object sensing device 17 sends a signal to the processor 2, the processor 2 turns on the display screen 3 and turns off the sterilizing device 11, and the signal transmission module 5 also sends an on signal to the electronic stethoscope 200 to start auscultation.

The electronic stethoscope further comprises a constant temperature device 18 electrically connected with the power supply module 1, the electronic stethoscope 200 is arranged on the constant temperature device 18 for heating, so that the vibrating diaphragm of the electronic stethoscope 200 is close to the body temperature, a patient does not feel that the electronic stethoscope 200 is cold during auscultation, the auscultation process is comfortable, and the electronic stethoscope is particularly suitable for cold regions in winter.

The constant temperature device 18 comprises a heating element 19, and the heating element 19 is positioned above the liquid storage cavity 12.

The thermostat 18 is also in signal connection with the processor 2. In use, when the electronic stethoscope 200 is placed on the thermostatic device 18, the object sensing device 17 senses the electronic stethoscope 200 and then sends a signal to the processor 2, the processor 2 turns on the thermostatic device 18 to heat the electronic stethoscope 200, the processor 2 turns off the display screen 3, and the signal transmission module 5 also sends a turn-off signal to turn off the electronic stethoscope 200, thereby ending the auscultation. When the electronic stethoscope 200 is picked up, the object sensing device 17 sends a signal to the processor 2, the processor 2 turns on the display screen 3 and turns off the thermostatic device 18, and the signal transmission module 5 also sends an on signal to the electronic stethoscope 200 to start auscultation.

Preferably, the thermostat sets an optimal temperature of 40 ℃ to allow the patient to obtain a more comfortable temperature.

An auscultation system, as shown in fig. 3, includes an electronic stethoscope 200, an earphone 300, and the above-mentioned detector 100. The signal transmission module 5 of the detecting instrument 100 is in signal connection with the electronic stethoscope 200, and the earphone 300 is in signal connection with the electronic stethoscope 200 or/and the signal transmission module 5.

Preferably, the signal transmission module 5 is a wireless communication module, the electronic stethoscope 200 and the earphone 300 are wireless devices, the signal transmission module 5 is in wireless communication connection with the electronic stethoscope 200, and the earphone 300 is in wireless communication connection with the electronic stethoscope 200 or/and the signal transmission module 5.

A control method, as shown in fig. 4 to 6, includes the following steps.

When the electronic stethoscope 200 is placed in the charger 7 for charging, the charger 8 sends a signal to the processor 2, and the processor 2 turns off the display 3 of the testing device 100. After the auscultation, the user charges on putting electronic stethoscope 200 on charger 7, and display screen 3 closes, can guarantee power consumption safety and information safety like this, avoids patient's information to reveal.

When the electronic stethoscope 200 is placed in the charger 7 for charging, the processor 2 controls the printer 6 to print a report. Therefore, the report can be quickly acquired when the auscultation is finished, complex steps are not needed, and the method is very quick.

When the electronic stethoscope 200 is removed from the charger 7, the electronic stethoscope 200 is automatically turned on. Thus, the electronic stethoscope 200 can be quickly started to auscultate when the auscultation is started, complex steps are not needed, and the auscultation is very quick.

When the earphone 300 is taken out of the charger 7, the processor 2 controls the signal transmission module 5 of the detecting instrument 100 to be in signal connection with the earphone 300, and the processor 2 sends a signal to the display screen 3 to prompt that the earphone 300 is connected. Thus, the earphone 300 can be quickly started to auscultate when the auscultation is started, complex steps are not needed, and the auscultation is very quick.

In addition, the following auscultation method is also included.

The display screen 3 senses a touch position representing a cardiopulmonary sound auscultation position touched by the user.

The processor 2 identifies the classified position of the touch position in the cardiopulmonary sound auscultation position identification program 43.

The signal transmission module 5 receives the cardiopulmonary sound signals sent by the electronic stethoscope.

The processor 2 converts the cardiopulmonary sound signals into cardiopulmonary sound signals to be classified.

The processor 2 compares the cardiopulmonary sound signal to be classified with the signal classification model in the cardiopulmonary sound signal classification program 42 and determines the type.

The processor 2 sends the type and the waveform of the cardiopulmonary sound signal to be classified to the display screen 3 for displaying.

The touch position is displayed in a position on the human body pattern displayed on the display screen 3.

When the cardiopulmonary sound signals to be classified do not reach the preset duration, the processor 2 sends out alarm signals to the display screen 3, and the display screen 3 displays an alarm.

The method also comprises a step that the display screen 3 issues a cardiopulmonary sound switching command to the processor 2.

The method also comprises a step that the storage 4 stores the cardiopulmonary sound signals to be classified obtained by the conversion of the processor 2 and the determined cardiopulmonary sound types for the user to look up.

Such simple structure, convenient to use, safe and durable can effectively solve traditional stethoscope and can not guarantee the automatic shutdown of instrument when charging, user forgets easily when suspending the use and shuts down, has power consumption potential safety hazard and information potential safety hazard, needs to be equipped with the problem of the high computer of expense.

While the invention has been described with reference to specific embodiments, the invention is not limited thereto, and various equivalent modifications and substitutions can be easily made by those skilled in the art within the technical scope of the invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (11)

1. The utility model provides a take cardiopulmonary sound auscultation detector of charger, detector (100) include power module (1), treater (2), display screen (3), accumulator (4), signal transmission module (5), and power module (1) is connected its characterized in that with treater (2), display screen (3), signal transmission module (5) electricity respectively: the detector (100) is internally provided with a charger (7) which is electrically connected with the power supply module (1) and used for charging the electronic stethoscope, and the charger (7) is in signal connection with the processor (2).

2. The cardiopulmonary sound auscultation detector with a charger of claim 1, wherein: the charger (7) is provided with an accommodating cavity (72) for accommodating the electronic stethoscope.

3. The cardiopulmonary sound auscultation detector with a charger of claim 1 or 2, wherein: the charger (7) is provided with a charging interface (71) which is used for being connected with the electronic stethoscope in a charging mode.

4. The cardiopulmonary sound auscultation detector with a charger of claim 1 or 2, wherein: the charger (7) is also used for charging the earphone.

5. The cardiopulmonary sound auscultation detector with a charger of claim 1 or 2, wherein: the detector (100) is internally provided with a printer (6) which is in signal connection with the processor (2).

6. An auscultation system, characterized by: comprising an electronic stethoscope (200), an earphone (300), and the detection instrument (100) according to any one of claims 1 to 5, wherein the signal transmission module (5) of the detection instrument (100) is in signal connection with the electronic stethoscope (200), and the earphone (300) is in signal connection with the electronic stethoscope (200) or/and the signal transmission module (5).

7. The auscultation system of claim 6, wherein: the signal transmission module (5) is a wireless communication module, the electronic stethoscope (200) and the earphone (300) are wireless devices, the signal transmission module (5) is in wireless communication connection with the electronic stethoscope (200), and the earphone (300) is in wireless communication connection with the electronic stethoscope (200) or/and the signal transmission module (5).

8. A control method characterized by: the method comprises the following steps:

when the electronic stethoscope (200) is placed in the charger (7) for charging, the charger (8) sends a signal to the processor (2), and the processor (2) closes the display screen (3) of the detector (100).

9. The control method according to claim 8, characterized by further comprising the steps of:

when the electronic stethoscope (200) is placed in the charger (7) for charging, the processor (2) controls the printer (6) to print a report.

10. The control method according to claim 8, characterized by further comprising the steps of: when the electronic stethoscope (200) is taken out from the charger (7), the electronic stethoscope (200) is automatically started.

11. The control method according to claim 8, characterized by further comprising the steps of: when the earphone (300) is taken out of the charger (7), the processor (2) controls the signal transmission module (5) of the detector (100) to be in signal connection with the earphone (300), and the processor (2) sends a signal to the display screen (3) to prompt that the earphone (300) is connected.

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