CN211862794U - Cardiopulmonary function monitor - Google Patents

Abstract

The utility model belongs to the technical field of medical equipment, in particular to a heart and lung function monitor, which comprises an electrocardiosignal acquisition module, an electrocardiosignal conditioning module, a nasal airflow sensor, a respiratory airflow signal conditioning module, a thoracic impedance acquisition module and a second microprocessor, wherein the second microprocessor receives processed three paths of lead signals, airflow signal data and thoracic impedance signals and displays the data through a first user interaction interface; the utility model provides a cardiopulmonary function monitor has overcome the drawback that prior art center function monitor guardianship measured data is simple relatively, has integrateed pulmonary function guardianship on current cardiac function monitor guardianship measuring basis and has measured and chest impedance measurement technique, has realized more cardiopulmonary parameters and has guardianship the measurement when, has made things convenient for medical personnel to realize the guardianship of multiple parameter on same platform monitor and has observed.

Description

Cardiopulmonary function monitor

Technical Field

The utility model belongs to the technical field of medical equipment, especially a cardiopulmonary function monitor.

Background

In the cardiac function monitor used in the prior art, the main monitoring parameters comprise electrocardio, heart rate, respiration frequency, blood oxygen saturation, blood pressure and the like, and the pulmonary function monitor is required for measuring and monitoring parameters such as vital capacity, body temperature, pulse and the like; that is, the existing cardiac function monitor has relatively simple monitoring and measuring parameters, limited changes of physiological indexes of patients to be monitored and measured, and fails to realize synchronous real-time measurement of cardiopulmonary function information of patients on the same monitor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome not enough among the prior art, provide a cardiopulmonary function monitor, realize the integrated innovation of current cardiac function monitor and pulmonary function monitor.

In order to achieve the above purpose, the utility model adopts the following technical scheme to realize:

a cardiopulmonary function monitor, comprising:

the electrocardiosignal acquisition module comprises three extraction electrodes and is used for acquiring three signals of different positions of the body surface of a user;

the electrocardiosignal conditioning module is used for receiving the three paths of signals extracted by the three extraction electrodes, carrying out differential processing, filtering and amplification on the three paths of signals to obtain three paths of processed electrocardiosignals and sending the processed electrocardiosignals to the first microprocessor, wherein the first microprocessor is used for carrying out A/D conversion on the processed three paths of electrocardiosignals to obtain three paths of lead signals in a digital form;

the nasal airflow sensor is arranged in a nostril of a user and is used for transmitting airflow in the nostril of the user to the respiratory airflow signal conditioning module;

the respiratory airflow signal conditioning module is used for detecting the pressure and the flow in the nares of the user by a pressure sensor and a flow sensor inside the module and transmitting data to the second microcontroller;

the thoracic impedance acquisition module comprises a signal extraction electrode, a high-frequency excitation output module, a voltage-controlled constant current source, an envelope detection circuit, an amplification circuit, a filter circuit and a level conversion circuit; the signal extraction electrode is arranged on the surface of a human body, and a corresponding voltage signal is measured after weak high-frequency constant current is applied so as to obtain a change signal of impedance; the high-frequency excitation output module is a DDS direct digital synthesizer, a main chip of the DDS direct digital synthesizer is AD9833 and is connected with an I/O pin of a microcontroller STM32, the excitation output frequency of the control module is configured through the output of the I/O pin, and the second microcontroller is connected with a thoracic impedance signal output end and receives a thoracic impedance signal after filtering and amplification;

a second microcontroller receiving the processed three-way lead signals, the airflow signal data, and the thoracic impedance signal and displaying the data via the first user interface.

Preferably, the cardiopulmonary function monitor further comprises:

and the microcontroller receives the data signal sent by the first microprocessor, stores the data, analyzes the data signal and gives an alarm for abnormal conditions.

Preferably, the cardiopulmonary function monitor further comprises:

the remote monitoring center is arranged at the nurse station;

and the Bluetooth communication module receives the data result analyzed by the microcontroller, and sends the data result to a second user interaction interface at the remote monitoring center for displaying, so that medical care personnel at the nurse station can monitor and follow up in time.

Preferably, the nasal airflow sensor is one of a differential pressure type flow rate sensor or a resistance type flow rate sensor.

Compared with the prior art, the utility model discloses following technological effect has:

the utility model provides a cardiopulmonary function monitor has overcome the drawback that prior art center function monitor guardianship measured data is simple relatively, has integrateed pulmonary function guardianship on current cardiac function monitor guardianship measuring basis and has measured and chest impedance measurement technique, has realized more cardiopulmonary parameters and has guardianship the measurement when, has made things convenient for medical personnel to realize the guardianship of multiple parameter on same platform monitor and has observed.

Drawings

Fig. 1 is a block diagram of the cardiopulmonary function monitor provided by the present invention.

Detailed Description

In order to make the technical means, creation characteristics, achievement purpose and efficacy of the utility model easy to understand and understand, the utility model is further clarified by combining the specific drawings.

It should be noted that, in the present invention, when an element is referred to as being "fixed" to another element, it may be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example 1

Referring to fig. 1, the present invention provides a cardio-pulmonary function monitor, which comprises an electrocardiographic signal acquisition module, an electrocardiographic signal conditioning module, a nasal airflow sensor, a respiratory airflow signal conditioning module, a thoracic impedance acquisition module, and a second microcontroller.

The electrocardiosignal acquisition module comprises three extraction electrodes and is used for acquiring electrocardio three-lead signals at different positions of the body surface of a user; the electrocardiosignal conditioning module receives electrocardio three-lead signals extracted by the three extraction electrodes, performs differential processing, filtering and amplification on the three signals to obtain processed electrocardiosignals, and sends the processed electrocardiosignals to the first microprocessor, wherein the first microprocessor is used for performing A/D conversion on the processed electrocardiosignals to obtain electrocardiosignals in a digital form;

the nasal airflow sensor is arranged in a nostril of a user and is used for transmitting airflow in the nostril of the user to the respiratory airflow signal conditioning module;

the respiratory airflow signal conditioning module is used for detecting the pressure and the flow in the nares of the user by a pressure sensor and a flow sensor inside the module, transmitting the data to the second microcontroller and calculating the current nares airflow flow rate of the user in the second microcontroller;

the thoracic impedance acquisition module comprises a signal extraction electrode, a high-frequency excitation output module, a voltage-controlled constant current source, an envelope detection circuit, an amplification circuit, a filter circuit and a level conversion circuit; the signal extraction electrode is arranged on the surface of a human body, after the excitation output module AD9833 sends out a high-frequency sine wave signal, a voltage-controlled constant current source circuit formed by AD8625 converts the high-frequency signal into a weak high-frequency constant current, applies the weak high-frequency constant current to the human body, and measures a corresponding voltage signal on the human body so as to obtain a carrier wave containing an impedance signal; the envelope detector extracts weak impedance signals from a carrier wave, and outputs human body thoracic impedance signals after passing through an amplifying circuit formed by AD620, a filter circuit formed by AD8626, a voltage raising and other signal processing circuits formed by ADI 3412;

and the second microcontroller receives the processed three-way lead signals, the airflow signal data and the thoracic impedance signal and displays the data through the first user interaction interface.

The utility model provides a cardiopulmonary function monitor has overcome the drawback that prior art center function monitor guardianship measured data is simple relatively, has integrateed pulmonary function guardianship on current cardiac function monitor guardianship measuring basis and has measured and chest impedance measurement technique, has realized more cardiopulmonary parameters and has guardianship the measurement when, has made things convenient for medical personnel to realize the guardianship of multiple parameter on same platform monitor and has observed.

Furthermore, the cardiopulmonary function monitor also comprises a microcontroller, wherein the microcontroller receives the data signals sent by the first microprocessor, stores the data, analyzes the data signals and gives an alarm for abnormal conditions. Therefore, medical staff can timely find the sudden cardio-pulmonary parameter abnormality of the user.

Further, in the present invention, the cardiopulmonary function monitor further comprises a remote monitoring center and a bluetooth communication module. The remote monitoring center is arranged at a nurse station, the Bluetooth communication module receives the data result analyzed by the microcontroller and sends the data result to the second user interaction interface at the remote monitoring center for displaying, and medical care personnel at the nurse station can monitor and follow the data result in time. The utility model discloses in, utilize bluetooth communication module to show the second user interactive interface who reaches remote monitoring center department on timely uploading of signal data that this heart and lung function monitor guardianship measured, so, a plurality of cardiopulmonary parameters of a plurality of users can be monitored simultaneously to the medical personnel of nurse station of body department, have alleviateed medical personnel's tour task.

The utility model discloses in, nasal cavity air current sensor be one of differential velocity of flow sensor or resistance-type velocity of flow sensor. Specifically, the nasal airflow sensor can detect the flow rate information of airflow in the nares of a user in real time, the flow rate information of the airflow in the nares of the user is uploaded to the respiratory airflow signal conditioning module, the respiratory airflow signal conditioning module immediately draws a change curve of respiratory airflow along with time t, the drawn change curve is uploaded to the microprocessor as airflow signal data, and when the respiratory airflow changes obviously and the change quantity of the respiratory airflow is larger than or equal to a preset threshold value, the microprocessor sends a signal to the microcontroller and sends an alarm signal.

The foregoing shows and describes the general principles, essential features, and features of the invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the description of the above embodiments and the description is only illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and these changes and modifications are all within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. A cardiopulmonary function monitor, comprising:

the electrocardiosignal acquisition module comprises three extraction electrodes and is used for acquiring three signals of different positions of the body surface of a user;

the electrocardiosignal conditioning module is used for receiving the three paths of signals extracted by the three extraction electrodes, carrying out differential processing, filtering and amplification on the three paths of signals to obtain three paths of processed electrocardiosignals and sending the processed electrocardiosignals to the first microprocessor, wherein the first microprocessor is used for carrying out A/D conversion on the processed three paths of electrocardiosignals to obtain three paths of lead signals in a digital form;

the nasal airflow sensor is arranged in a nostril of a user and is used for transmitting airflow in the nostril of the user to the respiratory airflow signal conditioning module;

a second microcontroller receiving the processed three-way lead signals, the airflow signal data and the thoracic impedance signal and displaying the data via a first user interface;

the respiratory airflow signal conditioning module is used for detecting the pressure and the flow in the nares of the user by a pressure sensor and a flow sensor inside the module and transmitting data to the second microcontroller;

the thoracic impedance acquisition module comprises a signal extraction electrode, a high-frequency excitation output module, a voltage-controlled constant current source, an envelope detection circuit, an amplification circuit, a filter circuit and a level conversion circuit; the signal extraction electrode is arranged on the surface of a human body, and a corresponding voltage signal is measured after weak high-frequency constant current is applied so as to obtain a change signal of impedance; the high-frequency excitation output module is a DDS direct digital synthesizer, a main chip of the DDS direct digital synthesizer is AD9833 and is connected with an I/O pin of a microcontroller STM32, the excitation output frequency of the control module is configured through the output of the I/O pin, and the second microcontroller is connected with a thoracic impedance signal output end and receives a thoracic impedance signal after filtering and amplification.

2. The cardiopulmonary function monitor of claim 1, wherein: further comprising:

and the microcontroller receives the data signal sent by the first microprocessor, stores the data, analyzes the data signal and gives an alarm for abnormal conditions.

3. The cardiopulmonary function monitor of claim 2, wherein: further comprising:

the remote monitoring center is arranged at the nurse station;

and the Bluetooth communication module receives the data result analyzed by the microcontroller, and sends the data result to a second user interaction interface at the remote monitoring center for displaying, so that medical care personnel at the nurse station can monitor and follow up in time.

4. The cardiopulmonary function monitor of claim 1, wherein: the nasal airflow sensor is one of a differential pressure type flow velocity sensor or a resistance type flow velocity sensor.

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