WO2010081433A1 - 电控动物心肺复苏装置 - Google Patents

电控动物心肺复苏装置 Download PDF

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Publication number
WO2010081433A1
WO2010081433A1 PCT/CN2010/070242 CN2010070242W WO2010081433A1 WO 2010081433 A1 WO2010081433 A1 WO 2010081433A1 CN 2010070242 W CN2010070242 W CN 2010070242W WO 2010081433 A1 WO2010081433 A1 WO 2010081433A1
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Prior art keywords
text display
tidal volume
way valve
programmable controller
regulator
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PCT/CN2010/070242
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English (en)
French (fr)
Inventor
黄子通
方向韶
陈礼雄
符岳
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中山大学附属第二医院
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Publication of WO2010081433A1 publication Critical patent/WO2010081433A1/zh

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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61DVETERINARY INSTRUMENTS, IMPLEMENTS, TOOLS, OR METHODS
    • A61D7/00Devices or methods for introducing solid, liquid, or gaseous remedies or other materials into or onto the bodies of animals
    • A61D7/04Devices for anaesthetising animals by gases or vapours; Inhaling devices
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M16/00Devices for influencing the respiratory system of patients by gas treatment, e.g. mouth-to-mouth respiration; Tracheal tubes
    • A61M16/021Devices for influencing the respiratory system of patients by gas treatment, e.g. mouth-to-mouth respiration; Tracheal tubes operated by electrical means
    • A61M16/022Control means therefor
    • A61M16/024Control means therefor including calculation means, e.g. using a processor
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M16/00Devices for influencing the respiratory system of patients by gas treatment, e.g. mouth-to-mouth respiration; Tracheal tubes
    • A61M16/10Preparation of respiratory gases or vapours
    • A61M16/12Preparation of respiratory gases or vapours by mixing different gases
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61MDEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
    • A61M2205/00General characteristics of the apparatus
    • A61M2205/50General characteristics of the apparatus with microprocessors or computers
    • A61M2205/502User interfaces, e.g. screens or keyboards

Definitions

  • the invention relates to an animal cardiopulmonary resuscitation device. Background technique
  • cardiopulmonary resuscitation consists of two parts: chest compressions and artificial ventilation.
  • basic research on cardiopulmonary resuscitation often uses small animals such as rats as research objects.
  • the common resuscitation method currently used in small animals after cardiac arrest is finger artificial chest compression. Because the heart rate of small animals is extremely fast, the frequency of artificial chest compression is not enough. Fast (requires a minimum of 200 times/min), the depth of the press is not constant enough, and the pressing position is often offset, which seriously affects the reliability of the research results.
  • the commercial small animal ventilator can not meet the requirements of mechanical ventilation and chest compression when the animal is resuscitated.
  • the purpose of this patent is to provide an electronically controlled animal cardiopulmonary resuscitation device that is capable of effectively performing high frequency, constant chest compressions and highly sensitive, proportional mechanical ventilation during cardiopulmonary resuscitation; all resuscitation parameters can be set as needed, adjusted Different cardiopulmonary resuscitation modes are combined to meet the requirements of the experiment; the set of resuscitation parameters can be observed in real time through an external oscilloscope; the actual value of tidal volume can be displayed in real time through the flow sensor on the display of the text display.
  • An electronically controlled animal cardiopulmonary resuscitation device comprising a gas supply regulating portion, a chest compression portion, a respiratory ventilation portion, and a programmable controller portion to which a text display is attached.
  • the air supply regulating portion is connected to the chest compression portion and the respiratory ventilation portion, respectively.
  • the programmable controller portion to which the text display is connected is connected to the air supply adjusting portion, the chest outer pressing portion, and the breathing venting portion, respectively.
  • the air supply adjusting portion includes two compressed air pressure regulators connected to a pipeline for conveying air, an oxygen regulator connected to a pipeline for supplying pure oxygen, a mixed oxygen regulator, a tidal volume regulator, and a tidal volume ventilation flow sensor. .
  • One of the compressed air regulators is directly connected to the cylinder press control solenoid valve of the chest outer pressing portion, and the other compressed air regulator is connected to the first input end of the hybrid oxygen regulator, and the second input of the hybrid oxygen regulator is The end is connected to the pipeline of the oxygen regulator that inputs pure oxygen, the output of the hybrid oxygen regulator is connected to the input of the tidal volume regulator, the output of the tidal volume regulator and the tidal volume ventilation flow sensing The input end of the device is connected, and the output of the tidal volume ventilation flow sensor is connected to the respiratory ventilation portion.
  • the text display is coupled to a tidal volume ventilation flow sensor.
  • the compressed air source is separately supplied to the two independent compressed air regulators, and the supply air regulating portion and the chest outer pressing portion are separately supplied for independently performing the animal breathing and ventilating actions and rapidly driving the pressing cylinder to reciprocate.
  • a hybrid oxygen regulator precisely adjusts the oxygen concentration required for animal breathing.
  • the tidal volume regulator precisely adjusts the amount of mixed oxygen tidal volume that the animal breathes.
  • the tidal volume ventilation flow sensor is a sensor that monitors the tidal volume flow in real time. By connecting with a text display, it can accurately display the moisture of the animal's breath in real time on the text display.
  • the respiratory ventilation part includes a gas passage connected to the animal's trachea, and the normally closed electric type.
  • a suction three-way valve and a normally open type electric exhalation three-way valve wherein the gas passage, the electric suction three-way valve and the electric exhalation three-way valve are connected to one another, and the electric suction three-way valve is further
  • the tidal volume ventilation flow sensor of the air supply regulating portion is connected, and the programmable controller connected with the text display is respectively connected to the electric suction three-way valve and the electric exhalation three-way valve.
  • Text display - The programmable controller directly sends an electrical signal to the electric suction three-way valve and the exhalation three-way valve, and the mechanical ventilation of the animal is completed by the alternating switch of the inspiratory three-way valve and the exhalation three-way valve.
  • the chest outer pressing portion includes a cylinder pressing control electric solenoid valve that presses a cylinder, an elevating bracket connected to the pressing cylinder, and a chest outer pressing portion.
  • the cylinder press control electric solenoid valve is coupled to a programmable controller to which a text display is connected.
  • the programmable controller connected with the text display is respectively connected to the tidal volume ventilation flow sensor, and the electric suction three-way valve and the electric exhalation three-way valve, and the chest
  • the cylinder of the outer pressing portion is pressed to control the electric solenoid valve connection and is connected to the digital oscilloscope.
  • the patent connects the text display and the programmable controller, so that the parameters set by the text display are sent to the electric suction three-way valve and the exhalation three-way valve through the programmable controller to issue any combination of electronic control commands.
  • the cylinder pressing control electric solenoid valve controls the mechanical ventilation part and the chest compression part respectively, the preset parameters of the multi-parameter combination instruction are displayed on the text display, and the flow rate of the tidal volume ventilation flow sensor is displayed in real time on the text display, and the chest compression is controlled.
  • the electrical signal waveforms of the various parameters of the mechanical ventilation are displayed on the digital oscilloscope.
  • Figure 1 is a schematic view showing the connection composition of the present invention.
  • FIG. 2 is a schematic illustration of the chest compression/breathing action of the present invention. detailed description
  • the electrically operated animal resuscitator for cardiopulmonary resuscitation of the present embodiment includes a gas supply regulating portion, a chest compression portion, and a respiratory ventilation portion. And a text display 12 to which a programmable controller is connected.
  • the respiratory ventilation portion includes a gas passage 11 connected to the trachea of the animal, a normally closed electric inspiratory three-way valve 9 and a normally open electric exhalation three-way valve 10, a gas passage 11, an electric suction three-way valve 9, and an electric exhalation valve.
  • the three-way valve 10 is connected to one place; the gas supply regulating portion includes two compressed air pressure regulators 3, 4 connected to the pipeline 1 for conveying air, an oxygen pressure regulator 5 connected to the pipeline 2 for conveying oxygen, and mixed oxygen Regulator 6, tidal volume regulator 7, tidal volume ventilation flow sensor 8.
  • One of the compressed air pressure regulators 3 is directly connected to the cylinder pressure control solenoid valve 13 of the chest compression portion, and the other compressed air pressure regulator 4 and the oxygen pressure regulator 5 are combined with the hybrid oxygen regulator 6, the tidal volume regulator 7
  • the tidal volume ventilation flow sensor 8 is connected.
  • the electric suction three-way valve 9 of the breathing ventilating portion is connected to the tidal volume ventilation flow sensor 8 of the air supply adjusting portion.
  • the programmable controller 12 to which the text display is connected is connected to the electric suction three-way valve 9, the electric exhalation three-way valve 10, and the cylinder press control solenoid valve 13, respectively, and the text display 12 is also connected to the tidal volume ventilation flow sensor 8.
  • the compressed air source 1 enters the compressed air regulator 3, 4 through the gas passage to adjust and outputs the air of the appropriate pressure.
  • the pure oxygen source 2 is regulated by the oxygen regulator 5 to output the oxygen of the appropriate pressure; according to the experimental requirements, the pressure is adjusted.
  • the air and oxygen are adjusted by the mixed oxygen regulator 6 to adjust the required mixed oxygen concentration, and the tidal volume adjuster 7 adjusts the required precise tidal volume to supply the animal for inhalation, and the tidal volume is fed back through the tidal volume ventilation flow sensor 8 For text displays.
  • the high level and low level signals are alternately issued to complete the inhalation and exhalation of the animal.
  • the electric command is often
  • the closed type electric suction three-way valve 9 is switched from the normally closed state to the open state, whereby the mixed oxygen enters the animal body, and at the same time, the normally open type electric exhalation three-way valve 10 is switched from the normally open state to the closed state.
  • the mixed oxygen can only enter the animal body and will not be excluded from the body, and the inhalation action is completed.
  • the normally closed type electric suction three-way valve 9 is The open state at the time of inhalation returns to the original closed state, and the mixed oxygen stops entering the animal body, while the normally open type electric exhalation three-way valve 10 returns from the closed state at the time of inhalation to the original open state due to the animal's thorax The natural retraction, the gas is excluded from the body, and the result is to complete the exhalation action.
  • the chest compression cylinder 14 is driven by the compressed air compressed by the compressed air regulator 3 to reciprocate. Complete the action of chest compressions.
  • the lifting bracket 15 can adjust the pressing depth and position according to the experimental requirements.
  • the entire air supply portion, mechanical ventilation, and chest compressions are collectively controlled by a text display 12 to which a programmable controller is coupled.
  • the resuscitation parameters can be set according to the experimental requirements through the text display 12 connected to the programmable controller, including: respiratory frequency, inspiration (expiration ratio), chest compression/mechanical ventilation ratio ( Chest compression : venti lation ratio), chest compression frequency, duty cycle (Compression-Decompression ratio), and chest compression start point and inspiration start The relationship of points, etc.
  • the electric signal from the text display 12 connected to the programmable controller is respectively transmitted to the electric suction three-way valve 9 and the electric exhalation three-way valve 10, and the cylinder pressing control electric solenoid valve 13 of the chest outer pressing portion, respectively controlling the machine
  • the ventilating portion and the chest compression portion, the preset parameters of the multi-parameter combination command are displayed on the text display 12, and the flow rate fed back by the tidal volume ventilation flow sensor 8 is displayed on the text display 12 in real time, and the parameters of the chest compression and mechanical ventilation are controlled.
  • the signal waveform is displayed on the digital oscilloscope 16.
  • Absorption ratio a: (100-a)

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  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Veterinary Medicine (AREA)
  • Anesthesiology (AREA)
  • Engineering & Computer Science (AREA)
  • Wood Science & Technology (AREA)
  • Zoology (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Percussion Or Vibration Massage (AREA)
  • Measurement Of The Respiration, Hearing Ability, Form, And Blood Characteristics Of Living Organisms (AREA)

Description

技术领域
本发明涉及一种动物心肺复苏装置。 背景技术
心肺复苏的核心包括两部分: 胸外按压和人工通气。 目前心肺复 苏基础研究常采用小动物如大鼠作为研究对象,在小动物心跳骤停后 当前研究的常用复苏手段是手指人工胸外按压, 由于小动物心率极 快, 人工胸外按压的频率不够快(要求最少达到 200次 /分钟)、 按压 的深度不够恒定,按压位置经常偏移,严重影响了研究结果的可靠性。 目前商品化的小动物呼吸机,不能满足动物复苏时候机械通气和胸外 按压按比例同歩联动的要求。
当前的复苏学研究需要对心肺复苏过程的每个复苏参数进行调 节,并对调节后的多个复苏参数按照研究的需要进行组合以得出最佳 的复苏方案, 这些复苏参数包括: 潮气量(tidal volume) , 吸入混合 氧浓度 (inspired oxygen concentration) , 呼吸步员率 (respiratory frequency) , 吸气 /呼气比例 (inspiration : expiration ratio)、 胸 夕卜按压 /机械通气比例 (chest compression : venti lation ratio)、 按 压深度 (chest compression depth)、 按压步员率 (chest compression frequency) , 按压周期(duty cycle) (胸外按压 /放松比例), 以及胸 外按压开始点和吸气开始点的关系等。当前缺乏专门的小动物心肺复 苏装置可以提供上述功能。 发明内容
本专利的目的是提供一种电控动物心肺复苏装置:能够在心肺复 苏时候有效进行高频、恒定的胸外按压和高灵敏、按比例联动机械通 气; 能按需设置所有的复苏参数, 调节出不同心肺复苏模式组合以满 足实验的要求; 可通过外接的示波器实时观察所设置的复苏参数组 合; 通过流量传感器在文本显示器的显示屏实时显示潮气量的实际 值。
为了实现上述目的, 本发明的技术方案为: 一种电控动物心肺复 苏装置, 它包括供气调节部分、 胸外按压部分、 呼吸通气部分和连接 有文本显示器的可编程控制器部分。所述供气调节部分分别与胸外 按压部分、 呼吸通气部分连接相通。 连接有文本显示器的可编程控 制器部分分别与供气调节部分、 胸外按压部分和呼吸通气部分连接 控制。
所述供气调节部分包括两个与输送空气的管道连接的压缩空气 调压器、 与输送纯氧的管道连接的氧气调压器、 混合氧调节器、 潮气 量调节器、潮气量通气流量传感器。其中一个压缩空气调压器直接与 所述胸外按压部分的气缸按压控制电磁阀连接,另一个压缩空气调压 器和混合氧调节器的第一输入端连接,混合氧调节器的第二输入端与 输入纯氧的氧气调压器的管道连接,混合氧调节器的输出端与潮气量 调节器的输入端连接,潮气量调节器的输出端和潮气量通气流量传感 器的输入端连接,潮气量通气流量传感器的输出端再与呼吸通气部分 连接。 所述文本显示器和潮气量通气流量传感器连接。 压缩空气源 分两路分别经过两个独立的压缩空气调压器,独立供应供气调节部分 和胸外按压部分,用于分别独立完成动物的呼吸通气动作和快速驱动 按压汽缸往复运动。混合氧调节器能精确调节动物呼吸所需要的氧浓 度。 潮气量调节器能精确地调节动物呼吸的混合氧气潮气量的大小。 潮气量通气流量传感器是实时监测潮气量流量大小的传感器,通过和 文本显示器连接, 能在文本显示器实时精确显示动物呼吸的潮气 所述呼吸通气部分包括与动物气管连接的气体通道、常闭型电动 吸气三通阀和常开型电动呼气三通阀, 所述气体通道、 电动吸气三通 阀和电动呼气三通阀连接相通于一处,所述电动吸气三通阀还与所述 供气调节部分的潮气量通气流量传感器连接, 所述连接有文本显示 器的可编程控制器分别与所述电动吸气三通阀和电动呼气三通阀 连接。 文本显示器-可编程控制器直接发出电信号到达电动吸气三通 阀和呼气三通阀, 通过吸气三通阀和呼气三通阀的交替开关, 完成动 物的机械通气。
所述胸外按压部分包括按压汽缸、 与该按压汽缸连接的升降支 架、胸外按压部分的气缸按压控制电动电磁阀。所述气缸按压控制电 动电磁阀与连接有文本显示器的可编程控制器连接。
所述连接有文本显示器的可编程控制器分别与潮气量通气流 量传感器连接、和所述电动吸气三通阀和电动呼气三通阀连接、和胸 外按压部分的气缸按压控制电动电磁阀连接, 并和数字示波器连接。 本专利通过文本显示器和可编程控制器的连接,使经过文本显 示器设定的参数经过可编程控制器发出任意组合的电控指令, 分别 传送给电动吸气三通阀和呼气三通阀、 以及气缸按压控制电动电磁 阀, 分别控制机械通气部分和胸外按压部分, 多参数组合指令的预设 参数显示于文本显示器, 潮气量通气流量传感器反馈的流量实时显 示于文本显示器, 控制胸外按压和机械通气的各个参数的电信号 波形显示于数字示波器。通过精确调节多个复苏参数, 输出可调节混 合氧气浓度的潮气量, 能够在心肺复苏时候有效进行高频、恒定的胸 外按压和高灵敏、按比例联动机械通气的同时, 设置任意的复苏多参 数组合指令, 并实时监测和显示实际的参数值。
附图说明
下面结合附图对本发明作进一歩的详细说明。
图 1是本发明的连接组成示意图。
图 2是本发明的胸外按压 /呼吸动作示意图。 具体实施方式
请参阅图 1和图 2,本实施例的电控动物心肺复苏装置 (Electric operated animal resuscitator for cardiopulmonary resuscitation)包括供气调节部分、胸外按压部分、 呼吸通气部分以 及连接有可编程控制器的文本显示器 12。呼吸通气部分包括与动物 气管连接的气体通道 11、 常闭型电动吸气三通阀 9和常开型电动呼 气三通阀 10, 气体通道 11、 电动吸气三通阀 9和电动呼气三通阀 10 连接相通于一处;供气调节部分包括两个与输送空气的管道 1连接的 压缩空气调压器 3、 4、 与输送氧气的管道 2连接的氧气调压器 5、 混 合氧调节器 6、 潮气量调节器 7、 潮气量通气流量传感器 8。 其中一 个压缩空气调压器 3直接与胸外按压部分的气缸按压控制电磁阀 13 连接,另一个压缩空气调压器 4和氧气调压器 5共同与混合氧调节器 6、 潮气量调节器 7、 潮气量通气流量传感器 8连接。 呼吸通气部分 的电动吸气三通阀 9与供气调节部分的潮气量通气流量传感器 8连 接。 连接有文本显示器的可编程控制器 12分别与电动吸气三通阀 9、 电动呼气三通阀 10和气缸按压控制电磁阀 13连接, 文本显示器 12还与潮气量通气流量传感器 8连接。
压缩空气源 1通过气体通道进入压缩空气调压器 3、 4调节后输 出合适压力的空气,纯氧气源 2通过氧气调压器 5调节后输出合适压 力的氧气; 按照实验需要, 调压后的空气和氧气通过混合氧调节器 6 调节出需要的混合氧浓度,通过潮气量调节器 7调节出需要的精确潮 气量供应动物吸气所需,并通过潮气量通气流量传感器 8将潮气量反 馈显示于文本显示器。
在连接有文本显示器的可编程控制器 12呼吸控制分系统的控制 下, 交替发出高电平和低电平信号, 完成动物的吸气、 呼气动作。 当 可编程控制器 12呼吸控制分系统发出高电平信号时候, 电指令使常 闭型电动吸气三通阀 9由平时的关闭状态转换为开放状态,由此混合 氧气进入动物体内, 与此同时常开型电动呼气三通阀 10由平时的常 开状态转换为关闭状态,混合氧气相应只能进入动物体内而不会排除 体外, 结果完成吸气动作; 当可编程控制器 12呼吸控制分系统发出 低电平信号时候,此常闭型电动吸气三通阀 9由吸气时候的开放状态 回复到原先的闭合状态, 混合氧气停止进入动物体内, 与此同时常开 型电动呼气三通阀 10由吸气时的闭合状态回复到原先的开放状态, 由于动物胸廓的自然回缩,气体相应排除体外,结果是完成呼气动作。
在可编程控制器 12气缸胸外按压控制分系统交替发出高电平和 低电平信号情况下, 胸外按压气缸 14在经过压缩空气调压器 3调压 后的压缩空气驱动下, 往复运动, 完成胸外按压的动作。 升降支架 15可根据实验要求调节按压深度和位置。
整个供气部分、机械通气和胸外按压由连接有可编程控制器的文 本显示器 12统一控制。 通过连接有可编程控制器的文本显示器 12, 可按实验需要设置复苏参数包括: 呼吸频率(respiratory frequency) , 吸气 /呼气比例 (inspiration : expiration ratio)、 胸 夕卜按压 /机械通气比例 (chest compression : venti lation ratio)、 按 压步员率 (chest compression frequency)、 按压周期 (duty cycle) (胸 夕卜按压 /放松比例, Compression-Decompression ratio ) , 以及胸夕卜 按压开始点和吸气开始点的关系等。连接有可编程控制器的文本显示 器 12发出的电信号分别传送给电动吸气三通阀 9和电动呼气三通阀 10、 和胸外按压部分的气缸按压控制电动电磁阀 13, 分别控制机械 通气部分和胸外按压部分,多参数组合指令的预设参数显示于文本显 示器 12, 潮气量通气流量传感器 8反馈的流量实时显示于文本显示 器 12, 控制胸外按压和机械通气的各个参数的电信号波形显示于 数字示波器 16。
如图 3所示对部分性能做出说明。 图中显示为两个 CPR周期(按 压 /呼吸比为 2: 1)。
(1) 胸外按压 /机械通气=^ 1 (N=l, 2, 3……任意整数), 本实例为 2: 1; 胸外按压 /机械通气比例和频率可根据研究需要进行 任意调节。
(2)按压周期=1): (100-b), b可为 0〜100范围内的任意数字, 一般预设为 50, 也就是按压: 放松 =1: 1; 按压周期可根据研究需 要进行任意调节。
(3) 吸呼比 =a: (100-a), a可为 0〜100范围内的任意数字, 本实例预设为 33.3, 也就是按压: 放松 =1: 2; 吸呼比可根据研究 需要进行任意调节。
(4) 按压开始点和吸气开始点的关系: 本实例是按压开始的同时送 气。按压开始点和吸气开始点的先后关系可根据研究需要进行任意调 节。

Claims

权利要求书
1、 一种电控动物心肺复苏装置, 它包括供气调节部分、 胸外按 压部分、 呼吸通气部分和连接有文本显示器的可编程控制器部分, 所述供气调节部分分别与胸外按压部分、 呼吸通气部分连接相通, 其 特征在于, 还包括连接有文本显示器的可编程控制器部分, 其分别 与供气调节部分、 胸外按压部分和呼吸通气部分连接控制。
2、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 所述供气调节部分包括两个与输送空气的管道连接的压缩空气调压 器、 与输送纯氧的管道连接的氧气调压器、 混合氧调节器、潮气量调 节器、潮气量通气流量传感器, 其中一个压缩空气调压器直接与所述 胸外按压部分的气缸按压控制电磁阀连接,另一个压缩空气调压器和 混合氧调节器的第一输入端连接,混合氧调节器的第二输入端与输入 纯氧的氧气调压器的管道连接,混合氧调节器的输出端与潮气量调节 器的输入端连接,潮气量调节器的输出端和潮气量通气流量传感器的 输入端连接, 潮气量通气流量传感器的输出端再与呼吸通气部分连 接, 输出可调节混合氧气浓度的潮气量, 所述文本显示器和潮气量 通气流量传感器连接。
3、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 所述呼吸通气部分包括与动物气管连接的气体通道、常闭型电动吸气 三通阀和常开型电动呼气三通阀,所述电动吸气三通阀还与所述供气 调节部分连接,所述连接有文本显示器的可编程控制器分别与所述 电动吸气三通阀和电动呼气三通阀连接。
4、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 所述胸外按压部分包括按压汽缸、与该按压汽缸连接的升降支架、胸 外按压部分的气缸按压控制电动电磁阀,所述气缸按压控制电动电磁 阀与连接有文本显示器的可编程控制器连接。
5、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 所述连接有文本显示器的可编程控制器分别与潮气量通气流量传 感器连接、 和所述电动吸气三通阀和电动呼气三通阀连接、 和胸 外按压部分的气缸按压控制电动电磁阀连接, 并和数字示波器连 接。
6、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 通过文本显示器和可编程控制器的连接,使经过文本显示器设定的 参数经过可编程控制器发出任意组合的电控指令, 分别传送给电动 吸气三通阀和呼气三通阀、 以及气缸按压控制电动电磁阀, 分别控制 机械通气部分和胸外按压部分。
7、根据权利要求 1所述的电控动物心肺复苏装置, 其特征在于, 通过连接有可编程控制器的文本显示器,可按实验需要设置的复苏参 数包括: 呼吸频率、 吸气 /呼气比例、 胸外按压 /机械通气比例、 按压 频率、胸外按压 /放松比例以及胸外按压开始点和吸气开始点的关系, 多参数组合指令的预设参数显示于文本显示器,潮气量通气流量传感 器反馈的流量实时显示于文本显示器,控制胸外按压和机械通气的 各个参数的电信号波形显示于数字示波器, 通过精确调节多个复苏 参数,输出可调节混合氧气浓度的潮气量,在心肺复苏有效进行高频、 恒定的胸外按压和高灵敏、按比例联动机械通气的同时设置任意的复 苏多参数组合指令, 并实时监测和显示实际的参数值。
PCT/CN2010/070242 2009-01-19 2010-01-18 电控动物心肺复苏装置 WO2010081433A1 (zh)

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CN201366067Y (zh) * 2009-01-19 2009-12-23 中山大学附属第二医院 电控动物心肺复苏装置
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US11179293B2 (en) 2017-07-28 2021-11-23 Stryker Corporation Patient support system with chest compression system and harness assembly with sensor system
CN110354362A (zh) * 2019-08-12 2019-10-22 杨豪 可控浓度的镇痛泵及其镇痛泵的控制方法
CN112515945B (zh) * 2020-11-30 2023-04-28 陕西科技大学 一种小型动物心肺复苏装置及其控制方法

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