CN218165269U

CN218165269U - Wireless electrocardiogram monitoring system in perioperative period

Info

Publication number: CN218165269U
Application number: CN202220822961.0U
Authority: CN
Inventors: 刘婷; 纪风涛; 李玉希; 罗建伟
Original assignee: Sun Yat Sen Memorial Hospital Sun Yat Sen University
Current assignee: Sun Yat Sen Memorial Hospital Sun Yat Sen University
Priority date: 2022-04-11
Filing date: 2022-04-11
Publication date: 2022-12-30
Anticipated expiration: 2032-04-11

Abstract

The utility model discloses a wireless electrocardio monitoring system of perioperative period, include the sleeve area and install the host computer in sleeve area, its characterized in that: the host computer on be provided with display screen, heart electrograph wire, body temperature wire, oxygen saturation wire, be provided with connection port on the host computer lateral wall to be provided with signal conversion module, control module, storage module, wireless transmission module, lithium cell in the host computer, the heart electrograph wire on be provided with the paster, the body temperature wire penetrate in the sleeve area to be provided with temperature probe on the body temperature wire, one of oxygen saturation wire serve and be provided with the oxygen saturation monitoring clamp. The utility model discloses all adopt disposable structure with heart electrograph wire, body temperature wire, oxygen saturation wire, make the patient from the admission to the operation to the discharge hospital can the everyone only adopt one set of clean heart electrograph wire, body temperature wire, reduce greatly because the patient cross infection that prison line used repeatedly leads to.

Description

Wireless electrocardiogram monitoring system in perioperative period

Technical Field

The utility model relates to the field of medical technology, specifically be wireless electrocardio monitoring system in perioperative period.

Background

In an operating room, the existing equipment for monitoring the vital signs of patients adopts a wired monitoring system, firstly, various lines are often encircled and are very messy due to the limited distance between an operating bed and an anesthesia monitor, and when the operating bed needs to be mobilized for various diseases of the patients in an operation, the lines are often accidentally torn off or torn off, so that potential safety hazards are caused to the monitoring of the vital signs of the patients, and the operation is often stopped to adjust the lines; secondly, in the existing wired monitoring life means, after the operation is finished, a patient needs to remove all guardianship, sends the patient to a recovery room and then connects a new guardianship again, and before the patient is sent to a ward, the patient needs to remove the wired guardianship and then connects various lines of the monitor again, so that great workload is caused to doctors and nurses, and the risk is high in the process that the patient removes the guardianship and transports the patient, and the change of the vital sign of the patient cannot be continuously monitored; thirdly, in the existing clinical work, after the patient carries out vital sign monitoring, various electrocardio monitoring lines are drawn and encircled, inconvenience is caused to various actions of the patient, if the patient needs to go out of bed for activities, such as going out for examination, eating, going to a toilet and the like, the monitoring lines on the body are particularly inconvenient, if the lines of the monitor are disconnected temporarily, the vital signs of the patient caused by the activities cannot be monitored, if a danger occurs, such as the patient falls down, a doctor cannot find the vital sign information of the patient of the monitor in time, and when the condition of the patient is judged, the rescue opportunity of the patient may be delayed; on the other hand, because the patient has limited freedom due to the monitoring of various lead lines, can only lie on the sickbed, has large psychological pressure, and is not beneficial to the rehabilitation of the patient, based on the wireless monitoring system, the patient can only accept one-time installation monitoring if the wireless monitoring system is adopted, and can monitor the patient through the receiving of the wireless system at any time and any place, thereby greatly improving the life safety of the patient.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the more confusion of easily taking place of current patient vital sign monitoring facilities circuit and leading to suspending the operation, need carry out dismouting monitoring facilities to the patient many times in patient's transfer process, the too much inconvenient patient's problem of activity of monitoring facilities circuit, a structural design is reasonable, can not lead to the operation to suspend because of the circuit confusion, do not need dismouting monitoring facilities in patient's transfer process, make things convenient for the patient to move about, avoid monitoring instrument used repeatedly to take place cross infection's wireless electrocardio monitoring system in operation phase.

The utility model provides a technical scheme that technical problem taken does:

wireless electrocardio monitoring system in perioperative period includes the cuff and installs the host computer on the cuff, its characterized in that: the main frame on be provided with display screen, heart electrograph wire, body temperature wire, oxygen saturation wire, be provided with interface on the host computer lateral wall to be provided with signal conversion module, control module, storage module, wireless transmission module, lithium cell in the main frame, the heart electrograph wire on be provided with the paster, the body temperature wire penetrate the cuff, and be provided with temperature probe on the body temperature wire, one of oxygen saturation wire serve and be provided with the oxygen saturation monitoring and press from both sides.

Preferably, the cuff is provided with a magic buckle to adjust the size of the cuff, the cuff is an existing sphygmomanometer cuff, the size of the cuff can be adjusted according to arms of different patients, the cuff is firmly fixed on the arm of the patient, and the stability of the host in the using process is improved.

Preferably, the host computer with heart electrograph wire, body temperature wire, oxygen saturation wire swing joint to set up heart electrograph wire, body temperature wire, oxygen saturation wire into the structure that can change from the host computer, adopt disposable structure with heart electrograph wire, body temperature wire, oxygen saturation wire activity, make the patient from the admission to the operation to the discharge hospital can only adopt one set of clean heart electrograph wire, body temperature wire per person, reduce greatly because the patient cross infection that leads to of guardianship line used repeatedly.

Preferably, connection port can be connected with arbitrary one or more equipment in the sphygmomanometer air pump, oxyhemoglobin saturation monitoring facilities, the breathing machine, the transfer pump, the syringe pump, the defibrillator, CRRT, PICCO, be connected host computer and sphygmomanometer air pump, be convenient for carry out blood pressure monitoring to the patient, be connected connection port on the host computer with multiple monitoring facilities, make the host computer become a equipment that has multiple monitoring function, make check out test set's circuit laminating on patient's skin, avoid the circuit to be connected with monitoring facilities after unsettled, can not lead to the operation to suspend because of the circuit drops, on the other hand, the parameter that the host computer collected multiple monitoring facilities is transmitted in the terminal, be convenient for medical staff long-range understanding patient vital sign, be favorable to patient's state of an illness accurate prejudgement.

Preferably, the control module is respectively connected with the display screen, the signal conversion module, the control module, the storage module, the wireless transmission module and the lithium battery, the signal conversion module is connected with the electrocardiogram lead, the body temperature lead, the oxygen saturation lead and the connecting port, signals monitored by various monitoring devices are transmitted into the signal conversion module, are converted into numbers or graphs by the signal conversion module and then are transmitted into the control module, the converted parameters are displayed in the display screen and stored in the storage module and are transmitted into a terminal in wireless connection with the host computer by the wireless transmission module, and various parameters displayed in the display screen enable a patient to visually see the change curves of various basic vital signs; basic vital sign parameters transmitted to the terminal are convenient for medical staff to remotely acquire and analyze the parameters, prevent and discover critical events of patients in advance, and facilitate early treatment and rescue.

Preferably, the host can be connected with any one or more terminals of a sphygmomanometer model display screen, a monitor, a mobile phone or a computer through a wireless transmission module, and transmits monitoring data acquired by the host into the connected terminal in a wireless transmission mode.

Preferably, any one of wireless transmission mode wiFi transmission, 2.4g frequency channel communication or bluetooth transmission, through wireless transmission, can with the host computer with the parameter transmission to the terminal that collects in, the medical staff of being convenient for long-range understanding patient's vital sign is favorable to the accurate prejudgement of the patient's state of an illness.

Preferably, the lithium battery is arranged to be replaceable from the main machine, and the lithium battery is arranged to be replaceable, so that electric energy can be provided for the operation of the main machine, and the number of lines is further reduced.

Has the advantages that:

1. the electrocardiogram lead, the body temperature lead and the oxygen saturation lead are in a disposable structure, so that each patient can only adopt one set of clean electrocardiogram lead, body temperature lead and oxygen saturation lead from hospital entrance to operation to hospital exit, and the cross infection of the patient caused by the repeated use of the monitoring lead is greatly reduced;

2. the host is connected with the air pump of the sphygmomanometer, so that the blood pressure of a patient can be monitored conveniently, the connection port on the host is connected with various monitoring devices, the host becomes a device with various monitoring functions, the line of the detection device is attached to the skin of the patient, the situation that the line is connected with the monitoring devices after being suspended from the body of the patient is avoided, operation is not stopped due to the line is avoided, on the other hand, parameters collected by the various monitoring devices are transmitted into the terminal by the host, medical staff can know vital signs of the patient remotely conveniently, and accurate pre-judgment of the state of the patient is facilitated;

3. signals monitored by various monitoring devices are transmitted into a signal conversion module, the signals are converted into numbers or graphs through the signal conversion module and then transmitted into a control module, the converted parameters are displayed in a display screen, stored in a storage module and transmitted into a terminal in wireless connection with a host through a wireless transmission module, and various parameters displayed in the display screen enable a patient to visually see various change curves of basic vital signs; basic vital sign parameters transmitted to the terminal are convenient for medical staff to remotely acquire and analyze the parameters, prevent and find critical events of patients in advance, and facilitate early treatment and rescue.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic diagram of a part of the structure of the present invention, illustrating the internal structure of the host.

In the figure: 1. sleeve belt, 2, host, 3, display screen, 4, connecting port, 5, electrocardiogram lead, 6, body temperature lead, 7, oxygen saturation lead, 8, patch, 9, temperature probe the system comprises an oxygen saturation monitoring clamp, 11, a signal conversion module, 12, a control module, 13, a storage module, 14, a wireless transmission module and 15, and a lithium battery.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

As shown in fig. 1-2, the wireless electrocardiographic monitoring system in the perioperative period comprises a cuff 1 and a host 2 installed on the cuff 1, and is characterized in that: host computer 2 on be provided with display screen 3, heart electrograph wire 5, body temperature wire 6, oxygen saturation wire 7, be provided with connection port 4 on 2 lateral walls of host computer to be provided with signal conversion module 11, control module 12, storage module 13, wireless transmission module 14, lithium cell 15 in host computer 2, heart electrograph wire 5 on be provided with paster 8, body temperature wire 6 penetrate in sleeve area 1 to be provided with temperature probe 9 on body temperature wire 6, oxygen saturation wire 7 serve and be provided with oxygen saturation monitoring clamp 10.

Preferably, the cuff 1 is provided with a hook-and-loop fastener to adjust the size of the cuff 1, the cuff 1 is an existing sphygmomanometer cuff 1, the size of the cuff 1 can be adjusted according to the arms of different patients, the cuff 1 is firmly fixed on the arms of the patients, and the stability of the host 2 in the using process is further improved.

Preferably, the host machine 2 is movably connected with the electrocardiogram lead 5, the body temperature lead 6 and the oxygen saturation lead 7, the electrocardiogram lead 5, the body temperature lead 6 and the oxygen saturation lead 7 are set to be replaceable from the host machine 2, the electrocardiogram lead 5, the body temperature lead 6 and the oxygen saturation lead 7 are movably arranged in a disposable structure, so that a patient can only adopt one set of clean electrocardiogram lead 5 and body temperature lead 6 from hospital admission to operation to hospital discharge, and the cross infection of the patient caused by the repeated use of the monitoring wire is greatly reduced.

Preferably, connection port 4 can be connected with the sphygmomanometer air pump, oxyhemoglobin saturation monitoring facilities, the breathing machine, the transfer pump, the syringe pump, the defibrillator, CRRT, any one or more equipment among the PICCO, be connected host computer 2 and sphygmomanometer air pump, be convenient for carry out blood pressure monitoring to the patient, be connected connection port 4 on host computer 2 and multiple monitoring facilities, make host computer 2 become an equipment that has multiple monitoring function, make check out test set's circuit laminating on patient's skin, avoid the circuit to be connected with monitoring facilities after unsettled, can not drop because of the circuit and lead to the operation to suspend, on the other hand, host computer 2 transmits the parameter that multiple monitoring facilities collected in the terminal, be convenient for medical staff long-range know patient's vital sign, be favorable to patient's state of an illness accurate prejudgement.

Preferably, the control module 12 is respectively connected with the display screen 3, the signal conversion module 11, the control module 12, the storage module 13, the wireless transmission module 14 and the lithium battery 15, and the signal conversion module 11 is connected with the electrocardiogram lead 5, the body temperature lead 6, the oxygen saturation lead 7 and the connection port 4, signals monitored by various monitoring devices are transmitted into the signal conversion module 11, are converted into numbers or graphs by the signal conversion module 11 and then are transmitted into the control module 12, the converted parameters are displayed in the display screen 3, are stored in the storage module 13 and are transmitted into a terminal wirelessly connected with the host computer 2 by the wireless transmission module 14, and various parameters displayed in the display screen 3 enable a patient to visually see the change curves of various basic vital signs; basic vital sign parameters transmitted to the terminal are convenient for medical staff to remotely acquire and analyze the parameters, prevent and discover critical events of patients in advance, and facilitate early treatment and rescue.

Preferably, the host 2 can be connected to any one or more terminals of the sphygmomanometer model display screen 3, the monitor, the mobile phone or the computer through the wireless transmission module 14, and transmits the monitoring data acquired by the host 2 to the connected terminals in a wireless transmission manner.

Preferably, wireless transmission mode 2.4g frequency channel communication mode transmission, through wireless transmission, can with host computer 2 with the parameter transmission to the terminal in that collects, the medical staff of being convenient for knows patient's vital sign remotely, be favorable to the accurate prejudgement of the patient's state of an illness.

Preferably, the lithium battery 15 is configured to be replaceable from the main unit 2, and the lithium battery 15 is configured to be replaceable, so that electric energy can be provided for the operation of the main unit 2, and the number of lines can be further reduced.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

The utility model discloses the part that does not relate to all is the same with prior art or can adopt prior art to realize.

Claims

1. Wireless electrocardio monitoring system of perioperative period includes the sleeve area and installs the host computer on the sleeve area, its characterized in that: the main frame on be provided with display screen, heart electrograph wire, body temperature wire, oxygen saturation wire, be provided with interface on the host computer lateral wall to be provided with signal conversion module, control module, storage module, wireless transmission module, lithium cell in the main frame, the heart electrograph wire on be provided with the paster, the body temperature wire penetrate the cuff, and be provided with temperature probe on the body temperature wire, one of oxygen saturation wire serve and be provided with the oxygen saturation monitoring and press from both sides.

2. The perioperative wireless electrocardiographic monitoring system according to claim 1, wherein: the cuff is provided with a magic buckle, so that the size of the cuff can be adjusted.

3. The perioperative wireless electrocardiographic monitoring system according to claim 1, wherein: the main machine is connected with the electrocardiogram lead, the body temperature lead and the oxygen saturation lead, and the electrocardiogram lead, the body temperature lead and the oxygen saturation lead are arranged into structures which can be replaced from the main machine.

4. The perioperative wireless electrocardiographic monitoring system according to claim 1, wherein: the connection port can be connected with any one or more of a sphygmomanometer air pump, oxyhemoglobin saturation monitoring equipment, a breathing machine, an infusion pump, an injection pump, a defibrillator, a CRRT and a PICCO.

5. The perioperative wireless electrocardiographic monitoring system according to claim 1 or 4, wherein: the control module is respectively connected with the display screen, the signal conversion module, the control module, the storage module, the wireless transmission module and the lithium battery, and the signal conversion module is connected with the electrocardiogram lead, the body temperature lead, the oxygen saturation lead and the connecting port.

6. The perioperative wireless electrocardiographic monitoring system according to claim 5, wherein: the host can be connected with any one or more terminals of a sphygmomanometer model display screen, a monitor, a mobile phone or a computer through the wireless transmission module, and transmits monitoring data acquired by the host into the connected terminals in a wireless transmission mode.

7. The perioperative wireless electrocardiographic monitoring system according to claim 6, wherein: the wireless transmission mode adopts any one of WiFi transmission, 2.4g frequency band communication or Bluetooth transmission.

8. The perioperative wireless electrocardiographic monitoring system according to claim 5, wherein: the lithium battery is arranged into a structure which can be replaced from the main machine.