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WO2021056265A1 - 注射泵、注射泵系统、注射泵控制方法及存储介质 - Google Patents

注射泵、注射泵系统、注射泵控制方法及存储介质 Download PDF

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Publication number
WO2021056265A1
WO2021056265A1 PCT/CN2019/107847 CN2019107847W WO2021056265A1 WO 2021056265 A1 WO2021056265 A1 WO 2021056265A1 CN 2019107847 W CN2019107847 W CN 2019107847W WO 2021056265 A1 WO2021056265 A1 WO 2021056265A1
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WO
WIPO (PCT)
Prior art keywords
syringe
pump
syringe pump
infusion
processor
Prior art date
Application number
PCT/CN2019/107847
Other languages
English (en)
French (fr)
Inventor
蒋霞
何丽娟
潘瑞玲
马连波
左鹏飞
Original Assignee
深圳迈瑞科技有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 深圳迈瑞科技有限公司 filed Critical 深圳迈瑞科技有限公司
Priority to PCT/CN2019/107847 priority Critical patent/WO2021056265A1/zh
Priority to CN201980098443.XA priority patent/CN114126686A/zh
Priority to EP19947116.0A priority patent/EP4035710A4/en
Publication of WO2021056265A1 publication Critical patent/WO2021056265A1/zh

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Classifications

    • 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
    • A61M5/00Devices for bringing media into the body in a subcutaneous, intra-vascular or intramuscular way; Accessories therefor, e.g. filling or cleaning devices, arm-rests
    • A61M5/14Infusion devices, e.g. infusing by gravity; Blood infusion; Accessories therefor
    • A61M5/142Pressure infusion, e.g. using pumps
    • A61M5/145Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons
    • A61M5/1452Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons pressurised by means of pistons
    • A61M5/1456Pressure infusion, e.g. using pumps using pressurised reservoirs, e.g. pressurised by means of pistons pressurised by means of pistons with a replaceable reservoir comprising a piston rod to be moved into the reservoir, e.g. the piston rod is part of the removable reservoir
    • 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
    • A61M2205/33Controlling, regulating or measuring
    • A61M2205/3331Pressure; Flow
    • 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
    • A61M2205/33Controlling, regulating or measuring
    • A61M2205/3368Temperature
    • 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
    • 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
    • A61M2205/505Touch-screens; Virtual keyboard or keypads; Virtual buttons; Soft keys; Mouse touches
    • 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
    • A61M2205/60General characteristics of the apparatus with identification means
    • A61M2205/6018General characteristics of the apparatus with identification means providing set-up signals for the apparatus configuration

Definitions

  • This application relates to the field of medical devices, and in particular to a syringe pump, a syringe pump system, a syringe pump control method, and a computer-readable storage medium.
  • Syringe pumps are widely used because they can provide more precise infusion tasks.
  • the preparation of the syringe pump before starting the infusion requires a relatively long waiting time. It requires the user to turn on, install the syringe, and set the infusion parameters in sequence, and the above operation is a serial setting, only the previous step is operated Only when the requirements are met can the next step be performed, and finally the infusion can be started.
  • the overall preparation time is relatively long. Especially in the case of emergency treatment of patients, such a long preparation time may even affect the treatment of patients.
  • the present application provides a syringe pump, a syringe pump system, a syringe pump control method, and a computer-readable storage medium, which can save the user's time in the infusion operation process.
  • the first aspect of the embodiments of the present application provides a method for controlling a syringe pump, which is applied to a syringe pump.
  • the syringe pump is used in conjunction with a syringe.
  • the syringe pump includes a pump body, a driving mechanism, a display screen, and a pump door.
  • the pump door is rotatably arranged on the pump body, and the injection pump control method includes:
  • the display screen is controlled to display an infusion parameter setting interface, where the infusion parameter setting interface includes infusion parameter setting items,
  • the infusion parameter setting item is used to present one or more infusion parameter contents
  • the driving mechanism is driven to move according to the content of at least one infusion parameter, so that the liquid in the syringe moves in the infusion direction.
  • the second aspect of the embodiments of the present application provides a syringe pump, which is used in conjunction with a syringe.
  • the syringe pump includes a pump body, a driving mechanism, a processor, a display screen, and a pump door.
  • the pump door is set to rotate.
  • the processor is used to control the display screen to display the infusion parameter setting interface when it is detected that the pump door is closed and the syringe is set in the syringe pump in a normal state.
  • the infusion parameter setting interface includes an infusion parameter setting item, the infusion parameter setting item is used to present one or more infusion parameter content; the processor is also used to drive the movement of the driving mechanism according to at least one infusion parameter content , So that the liquid in the syringe moves in the direction of infusion.
  • a third aspect of the embodiments of the present application provides a syringe pump system.
  • the syringe pump system includes a syringe and the syringe pump according to any one of the embodiments of the second aspect of the present application.
  • a fourth aspect of the embodiments of the present application provides a computer-readable storage medium, which is used to store a computer program for electronic data exchange, wherein the computer program causes a computer to execute a computer program as described in the first aspect of the present application. Part or all of the steps described in any method.
  • the control display screen displays the infusion parameter setting interface.
  • the user can use the infusion parameter setting interface Entering and/or confirming the infusion parameters can save the preparation time of the syringe pump before starting the infusion, and it can also reduce the problem of waiting for the push-pull mechanism to run for a preset time and then resist the piston handle before displaying the infusion parameter setting interface. Lack of wasted infusion time.
  • Fig. 1 is a flowchart of steps of a method for controlling a syringe pump in an embodiment of the present application.
  • Fig. 2 is a schematic diagram of the structure of a syringe pump in an embodiment of the present application.
  • Fig. 3 is a block diagram of the hardware structure of the syringe pump in an embodiment of the present application.
  • Fig. 4 is a schematic structural diagram of a syringe pump in another embodiment of the present application.
  • Fig. 5 is a schematic diagram of a syringe set in a syringe pump in an embodiment of the present application.
  • Fig. 6 is a schematic diagram of a state in which the pump door of the syringe pump is closed in an embodiment of the present application.
  • Fig. 7 is a schematic diagram of a state in which the push-pull mechanism is against the piston handle in an embodiment of the present application.
  • Fig. 8 is a schematic diagram of the syringe pump in an embodiment of the present application when the infusion operation is started.
  • FIG. 1 shows a flow chart of the steps of a method for controlling a syringe pump in an embodiment of the application.
  • the injection pump control method includes the following:
  • Step 141 Detect the state of the pump door and the setting state of the syringe in the syringe pump.
  • FIG. 2 is a schematic structural diagram of a syringe pump in an embodiment of the application.
  • the syringe pump 10 includes a pump body 110, a pump door 112 rotatably arranged on the pump body 110, a gripping mechanism 118 arranged on the pump body 110, a receiving groove 116 arranged at one end of the pump body 110, and a storage groove 116 arranged at The side end of the drive mechanism 133 can be brought down by the push-pull mechanism 114 that moves in a preset direction (such as the left-right direction).
  • the syringe pump 10 can work in the preparation phase of the infusion operation or the start-up phase of the infusion operation.
  • the preparation for the infusion operation includes setting the syringe 60 (shown in FIG. 5) in the syringe pump 10.
  • the syringe pump 10 controls the push-pull mechanism 114 to face the piston handle of the syringe 60 If the push-pull mechanism 114 is in contact with the piston handle 606 (shown in FIG.
  • the syringe pump 10 enters the infusion start operation phase; the infusion operation start phase is , The syringe pump 10 controls the liquid in the syringe 60 to move in the infusion direction according to the set infusion parameter settings.
  • the syringe pump 10 includes a control platform 102, a memory 104, a power supply system 106, an input/output (I/O) system 108, an RF circuit 120, an external port 122, an audio circuit 124, a monitoring circuit 126, a protection circuit 128, and a power drive circuit 130 , Pressure sensor 136, temperature sensor 138 and other components, these components communicate through one or more communication buses or signal lines 101.
  • the control platform 102 includes a processor 150 and a peripheral device interface 152.
  • the syringe pump 10 may be any medical device that executes the infusion operation set by the user according to the liquid configured by the user, and controls the input of the configured liquid medicine into the patient's body.
  • the syringe pump 10 can be used in conjunction with the syringe 60. It should be understood that the syringe pump 10 is only an example, and the components of the syringe pump 10 may have more or fewer components than shown, or have different component configurations.
  • the various components described in FIG. 3 may be implemented by hardware, software, or a combination of software and hardware, including one or more signal processing and/or application specific integrated circuits.
  • the memory 104 may include a high-speed random access memory, and may also include a non-volatile memory, such as one or more magnetic disk storage devices, flash memory devices, or other non-volatile solid-state storage devices.
  • the memory 104 may also include a memory remote from one or more processing/controllers 150, for example, a network-attached memory accessed via the RF circuit 120 or an external port 122 and a communication network (not shown), where The communication network may be the Internet, one or more intranets, a local area network (LAN), a wide area network (WLAN), a storage area network (SAN), etc., or a suitable combination thereof.
  • the processor 150 may control access to the memory 104 by other components of the syringe pump 10 except the peripheral device interface 152.
  • the peripheral device interface 152 couples the input and output peripherals of the syringe pump 10 to the processing/controller 150 and the memory 104.
  • the peripheral device interface 152 may include an input interface and an output interface.
  • the one or more processing/controllers 150 run various software programs and/or instruction sets stored in the memory 104 to perform various functions of the syringe pump 10 and process data.
  • the peripheral interface 152 and the processing/controller 150 may be implemented on a single chip. In one embodiment, they can be implemented on multiple discrete chips.
  • the processor 150 may be a central processing unit (Central Processing Unit, CPU), other general-purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), ready-made Field-Programmable Gate Array (FPGA) or other programmable logic devices, discrete gates or transistor logic devices, discrete hardware components, etc.
  • the general-purpose processor may be a microprocessor or the processor may also be any conventional processor or the like.
  • the RF (Radio Frequency) circuit 120 receives and transmits electromagnetic waves.
  • the RF circuit 120 converts electric signals into electromagnetic waves, or converts electromagnetic waves into electric signals, and communicates with communication networks and other communication devices via electromagnetic waves.
  • the RF circuit 120 may include well-known circuits for performing these functions, including but not limited to an antenna system 156, an RF transceiver, one or more amplifiers, a tuner, one or more oscillators, a digital signal processor, and a CODEC chip. Group, Subscriber Identity Module (SIM) card, memory, etc.
  • SIM Subscriber Identity Module
  • the network can be a World Wide Web (WWW), an intranet, and/or a wireless network such as a cellular telephone network, a wireless local area network (LAN), and/or a metropolitan area network. (MAN).
  • the wireless communication can use any of a variety of communication standards, protocols and technologies, including but not limited to Global System for Mobile Communications (GSM), Enhanced Data GSM Environment (EDGE), Wideband Code Division Multiple Access (WCDMA), Code Division Multiple Access (CDMA), Time Division Multiple Access (TDMA), Bluetooth (e.g. IEEE802.15.1), Wireless Fidelity (WIFI) (e.g.
  • IEEE802.11a, IEEE802.11b, IEEE802.11g and/or IEEE802.11n Voice over Internet Protocol (VoIP), Wi-MAX, protocols for e-mail, instant messaging and/or short message service (SMS), or any other suitable communication protocols, including those that have not been developed as of the submission date of this article Communication protocol.
  • VoIP Voice over Internet Protocol
  • Wi-MAX protocols for e-mail, instant messaging and/or short message service (SMS), or any other suitable communication protocols, including those that have not been developed as of the submission date of this article Communication protocol.
  • the external port 122 provides a wired communication interface between the syringe pump 10, other devices (such as Dock, central station, monitor, etc.) or users (computers or other communication devices). In an embodiment, it may be a communication interface controlled by the CAN bus protocol, a communication interface controlled by a serial communication protocol (for example, RS485, RS232), or a universal serial bus (USB).
  • the external port 122 is suitable for being directly or indirectly coupled to other devices or users via a network (such as the Internet, a LAN, etc.).
  • the audio circuit 124 and the speaker 154 provide an audio interface between the user and the syringe pump 10.
  • the audio circuit 124 receives audio data output from the peripheral device interface 152 through the output interface, converts the audio data into electrical signals, and transmits the electrical signals to the speaker 154.
  • the speaker 154 converts electrical signals into sound waves perceivable by humans.
  • the monitoring circuit 126 may include a fault detection circuit for prompting the status of one or more processes/controllers 150.
  • the protection circuit 128 may include a hardware protection device (for example, a fuse, a TVS diode) to protect the electrical safety of various components in the syringe pump 10.
  • the processing/controller 150 drives the power equipment (such as the driving mechanism 133) of the syringe pump 10 through the power drive circuit 130, so that the power equipment can controllably move under the drive of the processing/controller 150, and during the movement,
  • One or more force transmission/conversion devices (such as gears or transmission shafts) drive the controlled object (such as the pump door, the push-pull mechanism 114) to move.
  • the power equipment may be an electromagnetic device that realizes the conversion or transmission of electric energy according to the law of electromagnetic induction, such as a permanent magnet (PM) motor, a reactive (VR) motor and a hybrid (HB) motor.
  • the motor is driven by the processing/controller 150 to drive the control object (for example, the push-pull mechanism 114) of the syringe pump 10 to move, so that the control object realizes a preset motion state.
  • the pressure sensor 136 may respond to the pressure value of the object to be measured (such as the wall of the syringe 60), and convert the pressure value into an electrical signal that can be detected and send it to the control platform 102.
  • the pressure sensor 136 may be a resistance strain gauge pressure sensor, a semiconductor strain gauge pressure sensor, a piezoresistive pressure sensor, an inductive pressure sensor, a capacitive pressure sensor, a resonant pressure sensor, an optical fiber pressure sensor, or a capacitive acceleration sensor.
  • the syringe pump 10 has a heating device for heating the liquid in the syringe 60.
  • the temperature sensor 138 can be used to detect the real-time temperature of the liquid; at the same time, the temperature value is converted into an electrical signal for detection. It is sent to the control platform 102, and the control platform 102 can display the real-time temperature through the display screen 160, and can also control the heating device on/off according to the temperature value.
  • An input/output (I/O) system 108 provides an interface between the input/output peripherals of the syringe pump 10 and the peripheral device interface 152.
  • the input/output peripherals may be the display screen 160, the position sensor 164, the displacement sensor 166, the light assembly 168, and other input/control devices 162.
  • the I/O system 108 may include a display controller 140, a position sensor controller 144, a proximity sensor controller 146, a light controller 148, and one or more input controllers 142.
  • One or more controllers in the I/O system 108 receive/send electrical signals from/to input/output peripherals. Among them, one or more input controllers 142 receive/send electrical signals from/to other input/control devices 162.
  • the other input/control device 162 may include physical buttons (for example, push buttons, rocker buttons, touch buttons, etc.), slider switches, joysticks, and the like.
  • the other input/control device 162 may include a physical button for emergency stop of the infusion.
  • the display screen 160 provides an output interface between the syringe pump 10 and the user, which displays the electronic file on the screen through a specific transmission device and then reflects to the human eye; the display screen 160 may include a cathode ray tube display (CRT), plasma display PDP or liquid crystal display LCD, etc.
  • the display screen 160 may include a touch screen that provides an input/output interface between the syringe pump 10 and the user; the touch screen may include a resistive screen, a surface acoustic wave screen, an infrared touch screen, an optical touch screen, a capacitive screen, or a nano film It is an inductive display device that can receive input signals such as contacts.
  • visual output can be displayed to the user, for example, the visual output can be displayed to the user through an output interface in the peripheral device interface 152.
  • the visual output optionally includes graphics, text, charts, video, and combinations thereof. Some or all of the visual output may correspond to user interface objects, and more details of it will be described in the text.
  • the touch screen also accepts user input based on touch and/or contact.
  • the touch screen forms a touch-sensitive surface that receives user input.
  • the touch screen and display controller 140 (together with any associated modules and/or instruction sets in the memory 104) detects a contact on the touch screen (and any movement or interruption of the touch), and converts the detected contact to a display The interaction of user interface objects such as one or more soft keys on the touch screen.
  • the contact point between the touch screen and the user corresponds to one or more fingers of the user.
  • the touch screen may use LCD (Liquid Crystal Display) technology or LPD (Light Emitting Polymer Display) technology, but other display technologies may be used in other embodiments.
  • the touch screen and display controller 140 can use any one of a variety of touch-sensitive technologies to detect contact and its movement or interruption. These touch-sensitive technologies include but are not limited to capacitance, resistance, infrared and surface acoustic wave technologies, and others Proximity sensor array, or other technology used to determine one or more points of contact with the touch screen.
  • the position sensor 164 can sense the position of the measured object, convert the position into an electric signal for detection, and send the electric signal to the control platform 102 through the I/O system 108.
  • the position sensor 164 can be a contact sensor that generates a signal by two objects contacting and squeezing, such as a travel switch, a two-dimensional matrix position sensor; or a proximity sensor that generates a signal when two objects are close to a preset distance. Sensors, such as electromagnetic type, photoelectric type, differential transformer type, eddy current type, capacitive type, reed switch, ultrasonic type or Hall type.
  • the object to be measured may include a pump door and so on. In some embodiments, a Hall-type position sensor can be used to detect the position of the pump door.
  • the displacement sensor 166 can respond to the position change of the measured object relative to the reference position, convert the position change into an electric signal for detection, and send the electric signal to the control platform 102 through the I/O system 108.
  • the displacement sensor 106 may be inductive, capacitive, ultrasonic or Hall type.
  • the light assembly 168 may include a visual alarm element for prompting that the syringe pump 10 is in an abnormal state.
  • the lighting component 168 responds to the driving of the processing/controller 150 alone; the lighting component 168 can also cooperate with the speaker 154 to respond to the driving of the processing/controller 150.
  • the color or brightness of the light changes with the tone and frequency of the alarm sound. Variety.
  • the lighting component 168 may include indicator lights of components such as power supply, CPU, or infusion failure status warning lights.
  • the lighting assembly 168 may also include a visual lighting element for observing the structure or component status of the syringe pump 10 when the ambient light is poor.
  • the syringe pump 10 also includes a power system 106 for powering various components.
  • the power supply system 106 may include a power management system, one or more power sources (such as batteries or alternating current (AC)), a charging system, a power failure detection circuit, a power converter or inverter, and a power status indicator (such as a light emitting diode ( LED)), can also include any other components associated with power generation, management and distribution.
  • the software components include an operating system 170, a communication module (or instruction set) 172, a touch module (or instruction set) 174, a haptic feedback module (or instruction set) 176, and a motion module (or instruction set) 178 , Location module (or instruction set) 180, graphics module (or instruction set) 182, text input module (or instruction set) 190, device/global internal state (or instruction set) 192, and one or more applications (instruction set) ) 194.
  • an operating system 170 a communication module (or instruction set) 172, a touch module (or instruction set) 174, a haptic feedback module (or instruction set) 176, and a motion module (or instruction set) 178 , Location module (or instruction set) 180, graphics module (or instruction set) 182, text input module (or instruction set) 190, device/global internal state (or instruction set) 192, and one or more applications (instruction set) ) 194.
  • Operating system 170 (such as Darwin, RTXC, LINUX, UNIX, OS, WINDOWS and other embedded operating systems) includes control and management of conventional system tasks (such as memory management, storage device control, or power management, etc.), and help each Various software components and/or drivers that communicate between software and hardware components.
  • conventional system tasks such as memory management, storage device control, or power management, etc.
  • the communication module 172 facilitates communication with other devices via one or more external ports 122, and it also includes various software components for processing data received by the RF circuit 120 and/or the external ports 122.
  • the touch module 174 can selectively detect contact with the display screen 160 or other touch-sensitive devices (for example, touch buttons, touch pads).
  • the touch module 174 and the display controller 140 detect contact with the display screen 160 together.
  • the touch module 174 includes various software components for performing various operations associated with the detection of the contact (which may be by a finger or a touch pen, etc.) with the display screen 160, such as determining whether a contact has occurred (for example, detecting a finger pressing Time), determine the strength of the contact (such as the force or pressure of the contact), determine whether the contact moves (such as detecting one or more finger drag events), or track the movement on the display and determine whether the contact stops (such as detecting Finger lift time or contact break).
  • the operation of determining the movement of the contact point may include determining the velocity (amplitude), speed (amplitude and direction) and/or acceleration (including amplitude and/or direction) of the contact point. These operations can be applied to single-point contact or multiple-point simultaneous contact.
  • the touch module 174 detects the contact of other touch devices in conjunction with the display controller 140.
  • the touch module 174 may be used to detect the user's gesture input. Different gestures of the user on the touch-sensitive device have different contact patterns (for example, one or more combinations of the location, time, or intensity of the detected contact). For example, detecting a single-finger tap gesture includes detecting a finger pressing event, and then detecting a finger lifting event at the same or similar position as the finger pressing event. For example, detecting a finger swipe gesture on the surface of a touch device includes detecting a finger pressing event, then monitoring one or more finger drag events, and then detecting a finger lifting event. Similarly, taps, swipes, drags and other gestures of the touch pen are optionally detected by detecting a specific contact pattern of the touch pen.
  • the haptic feedback module 176 includes various software components for generating instructions to use one or more haptic output generators (not shown) in one or more positions of the syringe pump 10 in response to the user's interaction with the syringe pump 10. Tactile output is generated at the place. For example, after detecting the contact on the surface of the touch device, the color of the graphics or text of the touch device changes, or sounds or vibrations are generated.
  • the location module 180 includes software components for performing various operations related to detecting the location of the device and detecting changes in the location of the device.
  • the graphics module 182 includes various known software components for rendering or displaying graphics on the display screen 160 or the display screen of other external devices, including for changing the visual impact of the displayed graphics (such as brightness, transparency, saturation, Contrast or other visual properties).
  • graphics includes any object that can be displayed to the user, including, without limitation, text, web pages, icons (such as user interface objects such as soft keys), digital images, videos, animations, and the like.
  • the graphics module 182 stores data representing graphics to be used. Each graphic can be assigned a corresponding code.
  • the graphics module 182 receives one or more codes for specifying graphics to be displayed from an application program, etc., if necessary, also receives coordinate data and other graphics attribute data, and then generates screen image data for output to the display controller 140.
  • the text input module 190 provides various software components for inputting text in one or more application programs. Specifically, it can be used to input various infusion parameters, including drug name, infusion speed, or alarm threshold.
  • the memory 104 stores the device/global internal state 192.
  • the device/global internal state 157 includes one or more of the following: active application state, which indicates which application (if any) is currently active; display state, which indicates which application, view, or other information Occupies various areas of the display screen 160; sensor status, including information obtained from various sensors of the device and other input or control of the syringe pump 10; and position and/or orientation information about the location and/or posture of the device.
  • the memory 104 stores at least one application 194, and the application 194 may include an infusion mode device 194-1, a blocking pressure level setting 194-2, a medication setting 194-4, a volume setting 194-5, and a brightness setting 194- 6. Online setting 195-7, Dock setting 195-8 or temperature setting 195-9.
  • the infusion mode device 194-1 can include a combination of preset infusion parameters to meet the needs of different usage scenarios; wherein the obstruction pressure level setting 194-2 can include an interface that provides the user to input different obstruction pressure levels.
  • the blocking pressure can be adjusted to the blocking alarm threshold of the syringe pump 10 to meet the requirements of different usage scenarios.
  • the drug setting 194-4 can include an interface for users to input different drug names, drug abbreviations and/or drug colors, etc., by entering corresponding drug names/abbreviations/colors, etc., to set the drug parameters before infusion to facilitate infusion During the process, automatic confirmation inside the syringe pump 10 or verification by medical staff.
  • the volume setting 194-5 provides the user to adjust the alarm volume and/or the volume of other audio output according to the needs.
  • the brightness setting 194-6 provides the user to adjust the brightness of the screen brightness, alarm lights, lighting lights, etc. according to their needs.
  • the online setting 195-7 provides input interfaces for the user to control whether the syringe pump 10 and other equipment work online according to requirements, and the online working mode.
  • the Dock setting 195-8 provides a setting interface for the user to adjust the working parameters of the mounting seat (Dock) connected to the syringe pump 10 according to requirements.
  • the temperature device 195-9 provides an interface for the user to set the temperature of the liquid in the heating syringe.
  • FIG. 4 shows a schematic structural diagram of a syringe pump in another embodiment of the application.
  • the push-pull mechanism 114 includes a connecting rod 1142 and a push block 1140.
  • the push block 1140 is fixed to one end of the connecting rod 1142.
  • the connecting rod 1142 is slidably connected to the pump body 110 along its own axis.
  • the push-pull mechanism 114 can be connected along the drive mechanism 133.
  • the gripping mechanism 118 can be rotatably arranged on the pump body 112, and under the rotation operation of the user, the gripping mechanism 118 can be switched between the first state and the second state.
  • the user Before setting the syringe 60, the user can rotate the gripping mechanism 118 from the first state (as shown in FIG. 2) to the second state (as shown in FIG. 4), and pull the push-pull mechanism 114 away from the pump body 110.
  • the preset length for example, the push-pull mechanism 114 in FIG. 2 is pulled to the right by the preset length and then the push-pull mechanism 114 is located at the position shown in FIG. 4), so that the syringe pump 10 has enough space to install the syringe 60.
  • FIG. 5 shows a schematic diagram of a syringe set in a syringe pump in an embodiment of the application.
  • the syringe 60 includes a syringe body 602, a flange 604 provided at one end of the syringe body 602, and a piston handle 606.
  • the syringe body 602 is hollow for receiving the piston handle 606.
  • the piston handle 606 can be mounted on the syringe body 602. Move in the radial direction.
  • the user can turn the gripping mechanism 118 to the second state to press-fit the syringe body 602 on the pump body 110 of the syringe pump, and the flange 604 of the syringe 50 is received in the pump body
  • the distance between the receiving groove 116 of the 110, the piston handle 606 and the pushing block 1140 is a preset distance d (shown in FIG. 6).
  • a position sensor 164 may be provided in the pump door 112, and the processor 150 determines the state of the pump door 112 through a first position sensor provided in the pump door 112.
  • the state of the pump door 112 includes an open state and a closed state. status. As shown in FIG. 2, the processor 150 can determine that the pump door 112 is in an open state through a sensor provided in the first position.
  • FIG. 6, is a schematic diagram of a state where the pump door of the syringe pump is closed in an embodiment of the application. As shown in FIG. 6, the processor 150 may determine that the pump door 112 is in the closed state through the first position sensor.
  • the gripping mechanism 118 is provided with a second position sensor.
  • the gripping mechanism 118 is in the second state.
  • the second position sensor can transmit a feedback signal. Therefore, the processor 150 can detect whether the syringe 60 is installed in the syringe pump 10 through the second position sensor. For example, when the syringe 60 is set in the syringe pump 10, the gripping mechanism 118 fixes the syringe body 602 on the pump body 110, and the second position sensor can output a feedback signal.
  • the processor 150 can ensure that the syringe body 602 of the syringe 60 is press-fitted on the pump body 110 of the syringe pump 10.
  • a pressure sensor may be provided in the gripping mechanism 118, that is, when the syringe 60 is press-fitted on the pump body 110 of the syringe pump 10, the pressure sensor may contact the syringe 60 to generate a feedback signal with pressure information.
  • the processor 150 may also determine whether to press-fit the syringe 60 provided in the syringe pump 10 on the pump body 110 of the syringe pump 10 according to the received feedback signal with pressure information.
  • a third position sensor is provided in the receiving slot 116.
  • the flange 604 of the syringe 60 is received in the receiving groove 116.
  • the third position sensor can also output a feedback signal.
  • the processor 150 receives the feedback signal output by the third position sensor, the processor 150 can confirm that the flange 604 of the syringe 60 is received in the receiving groove 116.
  • the processor 150 can detect the state of the pump door 112 according to the first position sensor, and can also detect the setting state of the syringe 60 according to the second position sensor and the third position sensor. In this embodiment, when the second position sensor and the third position sensor both transmit feedback signals to the processor 150, the processor 150 can determine that the setting state of the injector 60 is normal; when the processor 150 does not receive the second position sensor and the first position sensor When the feedback signal is transmitted by any one of the three position sensors, the processor 150 can determine that the setting state of the injector 60 is abnormal.
  • the processor 150 when the processor 150 receives the feedback signal transmitted by the second position sensor sensor but does not receive the feedback signal transmitted by the third position sensor, it means that the flange 604 of the syringe 60 is received in the receiving groove 116, and the syringe 60 is detected.
  • the processor 150 receives the feedback signal transmitted by the third position sensor sensor but does not receive the feedback signal transmitted by the second position sensor, it means that the user has not turned the handle mechanism 118 to the second state, and the handle The mechanism 118 does not fix the syringe body 602 to the pump body 110, and the processor 150 can also detect that the setting state of the syringe 60 is abnormal.
  • the processor 150 determines that the setting state of the syringe 60 is abnormal, it controls the display screen 160 to output a prompt message indicating that the setting state of the syringe 60 is abnormal.
  • the processor 150 can also control the light assembly 168 to output the abnormal setting state of the syringe 60 through the light controller 148. Prompt information.
  • the syringe pump 10 can be in a shutdown state or a standby state. If the user uses the syringe pump 10 to perform the infusion task of the syringe 60, The user needs to open the pump door 112 of the syringe pump 10.
  • the processor 150 detects that the pump door 112 is opened through the first position sensor, the processor 150 controls the injection pump 10 to be powered on or perform a startup operation, so that the injection pump 10 is in the startup state.
  • the syringe pump 10 may perform a self-check operation to detect the device status of the syringe pump 10.
  • the self-check operation of the syringe pump 10 includes, but is not limited to, sound self-check, processor self-check, external storage device self-check, alarm lamp self-check, power supply self-check, and sensor self-check.
  • the processor 150 can control the speaker 154 to emit a sound through the audio circuit 124, and can determine whether the sound self-check is passed through the recording device; if the processor receives the sound from the speaker 154 through the recording device, it can determine that the sound is self-checking.
  • the inspection has passed, otherwise, it means that the equipment status of the syringe pump 10 is abnormal.
  • the processor 150 can run a preset program in the memory 104 and determine whether the result obtained after running the preset program is a preset result; if the result obtained after the preset program is treated is a preset result When the result is set, it can be determined that the processor self-check has passed, otherwise, it means that the equipment state of the syringe pump 10 is abnormal.
  • the processor 150 can also detect the external storage device, the lighting assembly 168, the power supply system 106, and multiple sensors.
  • each self-check operation When each self-check operation is passed, it can be determined that the equipment status of the syringe pump 10 is normal; when there is at least one self-check operation that fails, it is determined that the equipment status of the syringe pump 10 is abnormal, and the display screen 160 or the light assembly can be displayed. 168 Output prompt information of abnormal device status.
  • the existing technical solution may perform a self-check operation before setting the syringe 60 in the syringe pump 10, that is, after the syringe pump 10 completes the self-check operation, the pump door 112 is opened and the syringe 60 is set in the syringe pump 10, and then To a certain extent, the time in the preparation phase of the infusion task (or the preparation phase of the infusion operation) is increased.
  • the syringe pump 10 when the pump door 112 is opened, the syringe pump 10 performs a startup action, and performs a self-check operation at the same time during the process of setting the syringe 60 in the syringe pump 10, that is, by combining the self-check operation of the syringe pump 10 with the syringe pump 10
  • the setting of 60 is used for parallel processing, which helps to reduce the time in the preparation phase of the infusion task.
  • the syringe pump 10 may include a power button (including but not limited to a physical button or other types of buttons).
  • a power button including but not limited to a physical button or other types of buttons.
  • the power button When the power button is triggered, the user can open the pump door 112 to set the syringe 60 to the syringe pump 10. in. After that, the syringe pump 10 also performs a self-check operation during the process of setting the syringe 60 on the syringe pump 10, which can also achieve the purpose of reducing the time of the infusion task.
  • Step 143 When it is detected that the pump door is closed and the setting state of the syringe in the syringe pump is normal, control the display screen to display an infusion parameter setting interface.
  • the processor 150 when the processor 150 detects that the pump door 112 is closed and the setting state of the syringe 60 set in the syringe pump 10 is normal, the processor 150 can control the display screen 160 set on the pump door 112 to display the infusion parameter setting interface 510, wherein the infusion parameter setting interface 510 includes infusion parameter setting items, and the infusion parameter setting items are used to present one or more infusion parameter contents, including but not limited to infusion parameter contents such as infusion speed and infusion volume.
  • the driving mechanism 133 controls the push-pull mechanism 114 to start During the infusion operation, the driving mechanism 133 needs to move the pushing block 1140 toward the piston handle 606 by a preset distance d, so that the pushing block 1140 and the piston handle 606 are against (or in contact), and then the processor 150 is then set according to the infusion Parameter content for infusion action (or infusion operation).
  • the existing technical solution may control the display screen 160 to display the infusion parameter device interface 510 after the push block 1140 is against the piston handle 606, it takes a certain amount of time for the push block 1140 to move the preset distance against the piston handle 606. In this way, it will also increase the time for the infusion preparation phase.
  • FIG. 7 is a schematic diagram of a state in which the push-pull mechanism is against the piston handle in an embodiment of the application.
  • the processor 150 controls the display screen 160 to display the infusion parameter setting interface 510
  • the processor 150 drives the driving mechanism 133 to operate at the first motor speed.
  • the propulsion mechanism 114 is driven to move in a direction toward the piston handle 606 of the syringe 60, and the driving mechanism 133 moves at the first motor speed for a preset time after the propulsion mechanism 114 resists the piston handle 606.
  • the user controls the action of the push-pull mechanism 114 while performing the infusion parameter device through the infusion parameter device interface 510. In this way, it is also beneficial to reduce the time of the infusion operation.
  • Step 145 Drive the driving mechanism to move according to at least one infusion parameter content, so that the liquid in the syringe moves in the infusion direction.
  • the syringe pump 10 when the propulsion mechanism 114 is against the 606 piston handle, the syringe pump 10 can enter the infusion operation stage, and the processor 150 can drive the driving mechanism 133 to move at the second motor speed according to at least one infusion parameter content to control the syringe
  • the piston handle 606 of the 60 moves relative to the syringe body 602, so that the liquid in the syringe 60 moves in the infusion direction.
  • multiple display screens 160 may be provided on the pump door 112, for example, a first display screen and a second display screen.
  • the first display screen is used to display the infusion parameter setting interface 510
  • the second display screen is used to display the infusion parameter setting interface 510.
  • the display screen is used to display the functional operation interface 512.
  • the function operation interface 512 includes a progress bar display area 518, a menu button area 514 and a switch button area 516.
  • the processor 150 can control the progress bar display area 518 to have the first color information (such as green); When the operation is completed, the processor 150 can control the progress bar display area 518 to have the second color information (such as red); when the syringe pump 10 is not performing an infusion operation and the syringe 60 is not set in the syringe pump 10, the processor 150 can control the progress The bar display area 518 has third color information (eg, gray).
  • the first color information such as green
  • the processor 150 can control the progress bar display area 518 to have the second color information (such as red)
  • the processor 150 can control the progress
  • the bar display area 518 has third color information (eg, gray).
  • the user can set or operate the content in the infusion parameter device interface 510 by triggering the menu button area 514, and can determine whether to start the infusion operation.
  • the processor 150 is configured to detect a trigger event of the user on the infusion parameter setting interface 510, and adjust the content of the infusion parameter based on the trigger event.
  • the driving mechanism 133 drives the push-pull mechanism 114 at the first motor speed to move the preset distance d and then contacts the piston handle 606, if the user is still adjusting the content of the infusion parameters, the driving mechanism 133 can pause driving the push-pull mechanism 114, and the user After the setting is completed and the infusion instruction is started, the processor 150 then drives the driving mechanism 133 to move according to the content of the infusion parameter to start the infusion operation.
  • the infusion instruction is generated when the user triggers the start button after setting the infusion parameter content, or the infusion start instruction can be sent by the Dock.
  • the Dock can send the infusion start instruction to the corresponding syringe pump according to the sequence of the infusion operation of the multiple syringe pumps.
  • the Dock can send the start infusion instruction to the syringe pump in the second position after the first position in the sequence of the infusion operation, so as to make the infusion pump in the second position.
  • the injection pump in the position performs the infusion start operation after receiving the start infusion instruction sent by the Dock.
  • the user can complete the startup, shutdown or standby actions of the syringe pump 10 by triggering the switch button area 516.
  • a pressure sensor can be provided on the pushing block 1140.
  • the pressure sensor provided on the pushing block 1140 can output a feedback signal with pressure information to the processor 150, In turn, the processor 150 can determine that the pushing block 1140 is against the piston handle 606 when it determines that the feedback signal transmitted by the pressure sensor provided on the pushing block 1140 is received. In this way, when the processor 150 receives the feedback signals output by the second position sensor, the third position sensor, and the pressure sensor provided on the pushing block 1140, when the user receives the infusion start instruction after setting the infusion parameter content, The processor 150 may control the rotation speed of the second motor of the driving mechanism 133 according to the content of the set infusion parameters, so as to continue to perform the infusion operation.
  • FIG. 8 shows a schematic diagram of the infusion operation of the syringe pump in an embodiment of the application.
  • the push-pull mechanism 114 is used to clamp the piston handle 606 of the syringe 60.
  • the processor 150 in the syringe pump 10 issues commands such as rotation speed or position, and drives the power equipment (such as the drive mechanism 133) through the power drive circuit 130.
  • the drive mechanism 133 drives the screw rod 135 and the nut 137 through the deceleration mechanism to reduce the speed of the drive mechanism 133.
  • the rotation movement is converted into the linear movement of the nut 137.
  • the nut 137 is connected to the connecting rod 1142 of the syringe pump 10, and the connecting rod 1142 is connected to the pushing block 1140.
  • the pushing block 1140 can push the piston handle 660 of the matched syringe 60 for infusion.
  • the rotation speed of the driving mechanism 133 such as the second motor speed
  • the advancing speed of the matched syringe 60 can be adjusted, thereby adjusting the given infusion dose and infusion speed.
  • the processor 150 may display a tube installation guide interface on the first display screen, including but not limited to the setting direction of the syringe 60, and what needs to be paid attention to when setting. Matters, etc., to facilitate the user to accurately set the syringe 60.
  • the processor 150 may control the first display screen to display the tube installation guide interface when or before detecting that the setting state of the syringe 60 in the syringe pump 10 is detected as normal.
  • a display screen 160 is provided on the pump door 112. In this way, the infusion parameter setting interface 510 and the function operation interface 512 can be set in different sections of the display screen 160.
  • the processor 150 may determine the preset amount of liquid in the syringe 10. For example, the processor 150 determines the preset amount of liquid in the syringe 10 during the period from detecting that the pump door 112 is opened to when the pump door 112 is closed.
  • the processor 150 can detect the outer diameter information of the syringe 60 and the length information of the liquid in the syringe 60 in the length direction of the plunger 606 of the syringe 60 through the sensor, and then determine the preset of the liquid in the syringe 60 based on the outer diameter information and length information. ⁇ Volume information.
  • the user may also set preset amount information in the infusion parameter setting interface 510.
  • the processor 150 can also determine the volume of the infused liquid and the remaining liquid volume of the liquid in the syringe 60 according to the action of the driving mechanism 133.
  • the processor 150 may also determine the infusion progress information according to the remaining liquid volume information and the infusion parameter content, such as determining the remaining infusion time.
  • the processor 150 also controls the display screen 160 to display infusion progress information.
  • the syringe pump adopts a serial design in the preparation work flow before starting the infusion.
  • the self-test will be performed, and the status of the syringe will be recognized after the self-test is successful; the user opens the pump door to install the syringe, and it will push and pull
  • the mechanism is opened, and after the syringe is successfully set in the syringe pump and the push-pull mechanism is successfully clamped with the piston handle, the infusion parameter setting interface will be set on the screen for the user to edit or confirm. It takes tens of seconds for the push-pull mechanism to move from the farthest point to the gripping of the piston shaft. This process is very long and the user can only wait, which is very unreasonable.
  • the above-mentioned syringe pump control method is beneficial to reduce the time cost of the infusion task by processing the self-check operation of the syringe pump and the setting of the syringe in parallel.
  • the control display screen displays the infusion parameter setting interface, which can also reduce waiting for the push-pull mechanism to run for a preset time and then resist the piston handle. Display the insufficiency of wasting infusion time brought by the infusion parameter setting interface.
  • the above-mentioned injection pump control method detects and can control the action of the push-pull mechanism while inputting and/or confirming the infusion parameter through the infusion parameter device interface, which is also beneficial to reduce the time of the infusion operation. And in order to ensure the safety of the syringe pump, only after the push-pull mechanism and the piston handle are clamped correctly, and the infusion parameters of the syringe pump are set, the user can start the infusion, which effectively shortens the user’s waiting time and does not damage the syringe pump. Safe to use.
  • the disclosed device may be implemented in other ways.
  • the device embodiments described above are merely illustrative, for example, the division of the units is only a logical function division, and there may be other divisions in actual implementation, for example, multiple units or components may be combined or may be Integrate into another system, or some features can be ignored or not implemented.
  • the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, and may be in electrical or other forms.
  • the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, they may be located in one place, or they may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the solutions of the embodiments.
  • the functional units in the various embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units may be integrated into one unit.
  • the above-mentioned integrated unit can be implemented in the form of hardware or software functional unit.

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Abstract

一种注射泵(10)、注射泵系统、注射泵控制方法及计算机可读存储介质。该注射泵控制方法包括:检测泵门(112)的状态及注射器(60)在注射泵(10)中的设置状态(S141);在检测到所述泵门(112)被关闭且所述注射器(60)在所述注射泵(10)中的设置状态正常时,控制显示屏(160)显示输液参数设置界面(510)(S143);根据至少一个输液参数内容控制驱动机构(133)进行运动,以使所述注射器(60)内的液体按照输液方向移动(S145)。该方法可在检测到泵门(112)被关闭且注射器(60)在注射泵(10)中的设置状态正常时,控制显示屏(160)显示输液参数设置界面(510),如此亦可减少在等待推拉机构(114)运行预设时间后抵住活塞柄(606)后再显示输液参数设置界面(510)所带来的输注时间的浪费的不足。

Description

注射泵、注射泵系统、注射泵控制方法及存储介质 技术领域
本申请涉及医疗器械领域,尤其涉及一种注射泵、注射泵系统、注射泵控制方法及计算机可读存储介质。
背景技术
注射泵因其可提供较精准的输注任务,进而得到的广泛的应用。注射泵在启动输注之前的准备工作需要耗费比较长的等待时间,需要用户依次进行开机、安装注射器的安装和输液参数的设置的操作之后,且在上述操作为串行设置,只有上一步操作符合要求的情况下,才能进行下一步操作,最终才能启动输注,整体准备时间比较漫长。特别是在需要对患者进行紧急治疗的情况下,这么漫长的准备时间,甚至有可能影响患者治疗。
发明内容
本申请提供一种注射泵、注射泵系统、注射泵控制方法及计算机可读存储介质,可节省用户在输注操作过程的时间。
本申请实施例第一方面提供一种注射泵控制方法,应用于注射泵,所述注射泵用于与注射器配套使用,所述注射泵包括泵主体、驱动机构、显示屏及泵门,所述泵门转动设置于所述泵主体上,所述注射泵控制方法包括:
检测所述泵门的状态及所述注射器在所述注射泵中的设置状态;
在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常时,控制所述显示屏显示输液参数设置界面,其中,所述输液参数设置界面包括输液参数设置项,所述输液参数设置项用于呈现一个或多个输液参数内容;
根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动。
本申请实施例第二方面提供一种注射泵,所述注射泵用于与注射器配套使用,所述注射泵包括泵主体、驱动机构、处理器、显示屏及泵门,所述泵门转动设置于所述泵主体上;所述处理器用于在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常,控制所述显示屏显示输液参数设置界面,其中,所述输液参数设置界面包括输液参数设置项,所述输液参数设置项用于呈现一个或多个输液参数内容;所述处理器还用于根据至少一个所述输液参数内容驱动所述驱动机构的运动,以使所述注射器内的液体按照输液方向移动。
本申请实施例第三方面提供一种注射泵系统,所述注射泵系统包括注射器及如本申请第二方面实施例中任一项所述的注射泵。
本申请实施例第四方面提供一种计算机可读存储介质,所述计算机可读存储介质用于存储电子数据交换的计算机程序,其中,所述计算机程序使得计算机执行如本申请第一方面实施例任一方法中所描述的部分或全部步骤。
本申请实施例中,注射泵在检测到泵门被关闭且注射器在注射泵中的设置状态正常,控制显示屏显示输液参数设置界面,在推拉机构运行的过程中,用户可以通过输液参数设置界面对输液参数进行输入和/或确认,可以节省注射泵启动输注之前的准备时间,如此亦可减少在等待推拉机构运行预设时间后抵住活塞柄后再显示输液参数设置界面所带来的输注时间的浪费的不足。
附图说明
为了更清楚地说明本申请实施方式中的技术方案,下面将对实施方式描述中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本申请的一些实施方式,对于本领域普通技术人员来讲,在不付出创造性劳动性的前提下,还可以根据这些附图获得其他的附图。
图1是本申请一实施例中的注射泵控制方法的步骤流程图。
图2是本申请一实施例中注射泵的结构示意图。
图3是为本申请一实施例中注射泵的硬件结构框图。
图4是本申请又一实施例中注射泵的结构示意图。
图5是本申请一实施例中注射器设置于注射泵的示意图。
图6是本申请一实施例中注射泵的泵门被关闭的状态示意图。
图7是本申请一实施例中推拉机构抵住活塞柄的状态示意图。
图8是本申请一实施例中注射泵启动输注操作时的示意图。
具体实施方式
为了使本技术领域的人员更好地理解本申请方案,下面将结合本申请实施例中的附图,对本申请实施例中的技术方案进行清楚、完整地描述。所描述的实施例仅仅是本申请一部分实施例,而不是全部的实施例。基于本申请中的实施例,本领域普通技术人员在没有作出创造性劳动前提下所获得的所有其他实施例,都属于本申请保护的范围。
本申请的说明书和权利要求书及上述附图中的术语“第一”、“第二”等是用于区别不同对象,而不是用于描述特定顺序。此外,术语“包括”和“具 有”以及它们任何变形,意图在于覆盖不排他的包含。例如包含了一系列步骤或单元的过程、方法、系统、产品或设备没有限定于已列出的步骤或单元,而是可选地还包括没有列出的步骤或单元,或可选地还包括对于这些过程、方法、产品或设备固有的其他步骤或单元。
在本文中提及“实施例”意味着,结合实施例描述的特征、结构或特性可以包含在本申请的至少一个实施例中。在说明书中的各个位置出现该短语并不一定均是指相同的实施例,也不是与其它实施例互斥的独立的或备选的实施例。本领域技术人员显式地和隐式地理解的是,本文所描述的实施例可以与其它实施例相结合。如本文中所使用,根据上下文,术语“如果”可以被解释为“当……时”、“响应于确定”或“响应于检测到”等意思。类似地,根据上下文,短语“如果确定……”或“如果检测到【所陈述的条件或事件】”可以被解释为是指“在确定……时”、“响应于确定……”、“在检测到【所陈述的条件或事件】时”或“响应于检测到【所陈述的条件或事件】”的意思。
需要说明的是,对于以下的各方法实施例,为了简单描述,故将其都表述为一系列的动作组合,但是本领域技术人员应该知悉,本申请并不受所描述的动作顺序的限制,因为依据本申请,某些步骤可以采用其他顺序或者同时进行。
请参阅图1,所示为本申请一实施例中的注射泵控制方法的步骤流程图。该注射泵控制方法包括如下:
步骤141,检测泵门的状态及注射器在注射泵中的设置状态。
请一并参阅图2,所示为本申请一实施例中注射泵的结构示意图。注射泵10包括泵主体110、转动设置于泵主体110上的泵门112、设置于泵主体110上的夹柄机构118、设置于泵主体110一侧端的收容槽116及设置于收容槽116所在的侧端并可在驱动机构133的带到下沿预设方向(如左右方向)移动的推拉机构114。
本实施例中,注射泵10可工作于输注操作准备阶段或启动输注操作阶段。输注操作准备包括将注射器60(示于图5)设置于注射泵10内,在检测到注射器60在注射泵10中的设置状态正常后,注射泵10控制推拉机构114朝向注射器60的活塞柄606方向移动,若推拉机构114与注射器60的活塞柄606(示于图5)相接触后且接收到输注操作启动指令后,注射泵10进入启动输注操作阶段;启动输注操作阶段中,注射泵10根据设置的输液参数设置控制将注射器60内的液体按照输液方向移动。
请一并参阅图3,所示为本申请一实施例中注射泵的硬件结构框图。注射泵10包括控制平台102、存储器104、电源系统106、输入/输出(I/O)系统 108、RF电路120、外部端口122、音频电路124、监控电路126、保护电路128、动力驱动电路130、压力传感器136、温度传感器138等组件,这些组件通过一条或者多条通信总线或者信号线101进行通信。其中,控制平台102包括处理器150和外围设备接口152。
注射泵10可以是任何根据用户所配置的液体执行用户所设置的输注操作,将所配置的药液可控地输入患者体内的医疗设备。在一实施例中,该注射泵10可以与注射器60配套使用。应当理解,注射泵10只是一个实例,注射泵10的组件可以比图示具有更多或者更少的组件,或具有不同的组件配置。图3所述的各种组件可以用硬件、软件或者软硬件的组合来实现,包括一个或者多个信号处理和/或专用集成电路。
存储器104可包括高速随机存取存储器,并且还可包括非易失性存储器,例如一个或多个磁盘存储设备、闪存设备或其他非易失性固态存储设备。在某些实施例中,存储器104还可以包括远离一个或多个处理/控制器150的存储器,例如,经由RF电路120或者外部端口122以及通信网络(未示出)访问的网络附加存储器,其中所述通信网络可以是因特网、一个或多个内部网、局域网(LAN)、广域网(WLAN)、存储局域网(SAN)等,或其适当组合。处理器150可控制注射泵10的除了外围设备接口152之外的其他组件对存储器104的访问。
外围设备接口152将注射泵10的输入和输出外设耦接到处理/控制器150和存储器104。例如,外围设备接口152可包括输入接口及输出接口。该一个或多个处理/控制器150运行各种存储在存储器104中的软件程序和/或指令集,以便执行注射泵10的各种功能,并对数据进行处理。
在某些实施例中,外围设备接口152和处理/控制器150可以在单个芯片上实现。而在一实施例中,它们可以在多个分立的芯片上实现。处理器150可以是中央处理单元(Central Processing Unit,CPU),还可以是其他通用处理器、数字信号处理器(Digital Signal Processor,DSP)、专用集成电路(Application Specific Integrated Circuit,ASIC)、现成可编程门阵列(Field-Programmable Gate Array,FPGA)或者其他可编程逻辑器件、分立门或者晶体管逻辑器件、分立硬件组件等。通用处理器可以是微处理器或者该处理器也可以是任何常规的处理器等。
RF(射频)电路120接收并发送电磁波。该RF电路120将电信号转换为电磁波,或是讲电磁波转换为电信号,并且经由电磁波来与通信网络以及其他通信设备进行通信。该RF电路120可以包括用于执行这些功能的公知电路, 包括但不限于天线系统156、RF收发机、一个或多个放大器、调谐器、一个或多个振荡器、数字信号处理器、CODEC芯片组、用户身份模块(SIM)卡、存储器等。该RF电路120可以通过无线通信来与网络和其他设备进行通信,该网络可以是万维网(WWW)、内部网和/或诸如蜂窝电话网络等无线网络、无线局域网(LAN)和/或城域网(MAN)。所述无线通信可以使用多种通信标准、协议和技术中的任何一种,包括但不限于全球移动通信系统(GSM)、增强型数据GSM环境(EDGE)、宽带码分多址(WCDMA)、码分多址(CDMA)、时分多址(TDMA)、蓝牙(例如IEEE802.15.1)、无线保真(WIFI)(例如IEEE802.11a、IEEE 802.11b、IEEE802.11g和/或IEEE802.11n)、基于因特网协议的语音传输(VoIP)、Wi-MAX、用于电子邮件、及时消息传递和/或短消息服务(SMS)的协议,或任何其他合适的通信协议,包括在本文提交日尚未开发出的通信协议。
外部端口122提供了注射泵10、其他设备(例如Dock、中央站、监护仪等)或者用户(计算机或者其他通信设备)之间的有线通信接口。在一实施例中,可以是由CAN总线协议控制的通信接口,由串口通信协议控制(例如RS485、RS232)的通信接口,或者是通用串行总线(USB)。外部端口122适合于直接或者经网络(例如因特网、LAN等)间接耦接到其他设备或者用户。
音频电路124和扬声器154提供了用户与注射泵10之间的音频接口。音频电路124接收来自外围设备接口152通过输出接口输出的音频数据,将音频数据转换为电信号,并且将电信号传送到扬声器154。扬声器154将电信号转换为人类可感知的声波。
监控电路126可以包括故障检测电路,用于提示一个或者多个处理/控制器150的状态。
保护电路128可以包括硬件保护装置(例如保险丝、TVS二极管),用于保护注射泵10内的各个组件的用电安全。处理/控制器150通过动力驱动电路130对注射泵10的动力设备(如驱动机构133)进行驱动,使动力设备在处理/控制器150的驱动下可控地进行运动,并在运动过程中,通过一个或者多个力传动/转换设备(例如齿轮或者传动轴)带动控制对象(例如泵门、推拉机构114)进行运动。该动力设备可以是依据电磁感应定律实现电能转换或传递的一种电磁装置,例如永磁式(PM)电机,反应式(VR)电机和混合式(HB)电机。在一实施例中,电机在处理/控制器150的驱动下,带动注射泵10的控制对象(例推拉机构114)进行运动,使控制对象实现预设的运动状态。
在一实施例中,压力传感器136可以响应到被测对象(如注射器60的管壁)的压力值,并将所述压力值转换为可供检测的电信号发送给控制平台102。该压力传感器136可以是电阻应变片压力传感器、半导体应变片压力传感器、压阻式压力传感器、电感式压力传感器、电容式压力传感器、谐振式压力传感器、光纤压力传感器或者电容式加速度传感器。
在一实施例中,注射泵10具有加热设备,用来加热注射器60内的液体,此时温度传感器138可以用来检测液体的实时温度;同时将所述温度值转换为可供检测的电信号发送给控制平台102,控制平台102可以将实时温度通过显示屏160进行显示,也可以根据该温度值对加热设备进行开/关控制。
输入/输出(I/O)系统108提供注射泵10的输入/输出外设和外围设备接口152之间的接口。输入/输出外设可以是显示屏160、位置传感器164、位移传感器166、灯光组件168以及其他输入/控制设备162。该I/O系统108可以包括显示控制器140、位置传感器控制器144、接近传感器控制器146、灯光控制器148和一个或多个输入控制器142。该I/O系统108中的一个或多个控制器接收/发送来自/去往输入/输出外设的电信号。其中,一个或多个输入控制器142接收/发送来自/去往其他输入/控制设备162的电信号。该其他输入/控制设备162可以包括物理按钮(例如按压按钮、摇杆按钮或触摸按钮等)、滑块开关、操纵杆等。在一实施例中,其他输入/控制设备162可以包括用于紧急停止输注的物理按钮。
在一实施例中,显示屏160提供注射泵10与用户之间的输出接口,其将电子文件通过特定的传输设备显示到屏幕上再反射到人眼;该显示屏160可以包括阴极射线管显示器(CRT),等离子显示器PDP或液晶显示器LCD等。在一些实施例,显示屏160可以包括触摸屏,该触摸屏提供注射泵10与用户之间的输入/输出接口;该触摸屏可以包括电阻屏、表面声波屏、红外触摸屏、光学触摸屏、电容屏或者纳米膜等,其为可接收触头等输入信号的感应式显示装置。无论是显示屏还是具有触摸屏的显示屏,都可以向用户显示视觉输出,如通过外围设备接口152中的输出接口向用户显示视觉输出。视觉输出任选地包括图形、文本、图表、视频以及它们的组合。某些或所有视觉输出可与用户接口对象相对应,在文中将对它的更多细节进行描述。
触摸屏还基于触觉和/或接触来接受用户的输入。该触摸屏形成一个接收用户输入的触摸敏感表面。该触摸屏和显示控制器140(连同存储器104中任何相关联的模块和/或指令集一起)检测触摸屏上的接触(以及所述触摸的任何移动或中断),并且将检测到接触转换成与显示在触摸屏上的诸如一个或多 个软按键之类的用户界面对象的交互。在一实施例中,触摸屏与用户之间的接触点对应于用户的一个或多个手指。该触摸屏可以使用LCD(液晶显示器)技术或LPD(发光聚合物显示屏)技术,但在其他实施例中可以使用其他显示技术。触摸显示屏与显示控制器140可以使用多种触敏技术中的任何一种来检测接触及其移动或中断,这些触敏技术包括但不限于电容、电阻、红外和声表面波技术,以及其他接近传感器阵列,或用于确定与触摸显示屏相接触的一个或多个点的其他技术。
位置传感器164可以感知到被测对象的位置,并将所述位置转换为可供检测电信号,并将该电信号通过I/O系统108发送给控制平台102。该位置传感器164可以是由两个物体接触挤压而产生信号的接触式传感器,例如行程开关、二维矩阵式位置传感器;也可以是由两个物体接近到预设距离而产生信号的接近式传感器,例如电磁式、光电式、差动变压器式、电涡流式、电容式、干簧管、超声波式或者霍尔式。该被测对象可以包括泵门等。在某些实施例中,可以使用霍尔式位置传感器对泵门的位置进行检测。
位移传感器166可以响应到被测物体相对于参考位置的位置变化,并将所述位置变化转换为可供检测电信号,并将该电信号通过I/O系统108发送给控制平台102。该位移传感器106可以是电感式、电容式、超声波式或者霍尔式。
灯光组件168可以包括用于提示注射泵10处于异常状态的可视化报警元件。灯光组件168单独响应处理/控制器150的驱动;灯光组件168也可以与扬声器154相对应的配合以响应处理/控制器150的驱动,例如灯光随着报警声的声调、频率而发生颜色或者亮度变化。灯光组件168可以包括电源、CPU等组件的指示灯或者输液故障状态报警灯。灯光组件168也可以包括用于在环境光线不良时,便于观察注射泵10的结构或者组件状态的可视化照明元件。
注射泵10还包括用于为各种组件供电的电源系统106。该电源系统106可以包括电源管理系统、一个或多个电源(例如电池或者交流电(AC))、充电系统、电源故障检测电路、电源转换器或逆变器、电源状态指示器(例如发光二极管(LED)),也可以包括电能生成、管理和分布相关联的其他任何组件。
在一实施例中,软件组件包括操作系统170、通信模块(或指令集)172、触控模块(或指令集)174、触觉反馈模块(或指令集)176、运动模块(或指令集)178、位置模块(或指令集)180、图形模块(或指令集)182、文本输入模块(或指令集)190、设备/全局内部状态(或指令集)192、以及一个或者多个应用(指令集)194。
操作系统170(例如Darwin、RTXC、LINUX、UNIX、OS、WINDOWS等嵌入式操作系统)包括用于控制和管理常规系统任务(例如内存管理、存储设备控制或者电源管理等),以及有助于各种软硬件组件之间通信的各种软件组件和/或驱动器。
通信模块172有助于经一个或多个外部端口122而与其他设备进行通信,并且它还包括用于处理RF电路120和/或外部端口122接收的数据的各种软件组件。
在一实施例中,触控模块174可以选择地检测与显示屏160或者其他触敏设备(例如触摸按钮、触摸板)的接触。例如触控模块174与显示控制器140一同检测与显示屏160的接触。触控模块174包括用于执行与显示屏160的接触(可以通过手指或者触摸笔等)检测相关联的各种操作的各种软件组件,所述操作例如确定是否发生接触(例如检测手指按下时间)、确定接触的强度(例如接触的力或者压力)、确定该接触是否移动(例如检测一个或者多个手指拖动事件),或者追踪显示屏上的移动并且确定该接触是否停止(例如检测手指抬起时间或者接触断开)。其中确定接触点移动的操作可以包括确定接触点的速率(幅度)、速度(幅度和方向)和/或加速度(包括幅度和/或方向)。这些操作可以是应用于单点接触或者多点同时接触。在一实施例中,触摸模块174结合显示控制器140一同检测其他触摸设备的接触。
触控模块174可以用于检测用户的手势输入。用户在触敏设备上的不同手势具有不同的接触模式(例如,检测到接触的位置、时间或者强度中的一个或者多个组合)。例如,检测单指轻击手势包括检测手指按下事件,然后在与手指按下事件相同或者相近位置处检测手指抬起事件。例如,检测触摸设备表面上的手指轻扫手势包括检测手指按下事件,然后监测一个或者多个手指拖动事件,并且随后检测到手指抬起事件。类似地,通过检测触摸笔的特定接触图案来任选地检测触摸笔的轻击、轻扫、拖动和其他手势。
触觉反馈模块176包括用于生成指令的各种软件部件,以响应于用户与注射泵10的交互而使用一个或者多个触觉输出发生器(图未示)在注射泵10的一个或多个位置处产生触觉输出。例如检测触摸设备表面的接触之后,触摸设备的图形或者文字的颜色发生变化,或者产生声音或者震动。
位置模块180包括用于执行与检测设备位置以及检测设备位置变化相关的各种操作的软件部件。
图形模块182包括用于在显示屏160或者其他外部设备的显示屏上渲染或者显示图形的各种已知软件部件,包括用于改变所显示的图形的视觉冲击(例 如亮度、透明度、饱和度、对比度或者其他视觉属性)的部件。在本文实施例中,术语“图形”包括可被显示给用户的任何对象,非限制性包括文本、网页、图标(例如软键的用户界面对象)、数字图像、视频、动画等。在某些实施例中,图形模块182存储表示待使用图形的数据。每个图形可以被分配有对应的代码。图形模块182从应用程序等接收用于指定待显示的图形的一个或者多个代码,在必要的情况下还一起接收坐标数据和其他图形属性数据,并随后生成屏幕图像数据以输出至显示控制器140。
文本输入模块190提供用于在一个或者多个应用程序中输入文本的各种软件部件。具体的,可以用来输入各种输注参数,包括药品名称、输液速度或者报警阈值等。
在一实施例中,存储器104存储设备/全局内部状态192。设备/全局内部状态157包括以下中的一者或多者:活动应用程序状态,其指示哪些应用程序(如果有的话)当前是活动的;显示状态,其指示什么应用程序、视图或其它信息占据显示屏160的各个区域;传感器状态,包括从设备的各个传感器和其他输入或控制注射泵10获取的信息;以及关于设备的位置和/或姿态的位置和/或方位信息。
在一实施例中,存储器104存储至少一个应用194,该应用194可以包括输液模式设备194-1、阻塞压力等级设置194-2、药物设置194-4、音量设置194-5、亮度设置194-6、联机设置195-7、Dock设置195-8或者温度设置195-9。其中,输液模式设备194-1可以包括预设输注参数的组合,以适应不同使用场景的需求;其中阻塞压力等级设置194-2可以包括提供用户输入不同的阻塞压力等级的接口,通过输入不同的阻塞压力可以调整注射泵10的阻塞报警阈值,以适应不同使用场景的需求。其中药物设置194-4可以包括提供用户输入不同药品名称、药品简称和/或药品颜色的接口等,通过输入相应的药品名称/简称/颜色等进行输液前的药物参数设置,以便于在输注过程中,注射泵10内部的自动确认或者医护人员的核对。其中音量设置194-5提供了用户根据需求调整报警音量和/或其他音频输出的音量大小。其中亮度设置194-6提供了用户根据需求调整屏幕亮度、报警灯、照明灯等亮度大小。其中联机设置195-7提供了用户根据需求控制注射泵10与其他设备是否进行联机工作,联机工作模式等输入接口。其中Dock设置195-8提供了用户根据需求调整与注射泵10相连接的安装座(Dock)的工作参数的设置接口。其中温度设备195-9提供了用户对加热注射器内液体温度的设置接口。
请一并参阅图4,所示为本申请又一实施例中注射泵的结构示意图。推拉 机构114包括连接杆1142及推动块1140,推动块1140固定于连接杆1142的一端,连接杆1142沿自身轴向滑动连接于泵主体110,推拉机构114在驱动机构133的带动来可沿连接杆1142的轴向移动。夹柄机构118可转动设置于泵主体112上,在用户的转动操作下,夹柄机构118可在第一状态与第二状态之间进行切换。在设置注射器60之前,用户可将夹柄机构118由第一状态转动(如图2所示)至第二状态(如图4所示),并将推拉机构114以远离泵主体110的方向拉出预设长度(如将图2中推拉机构114向右拉出预设长度后推拉机构114位于图4所示的位置),以使得注射泵10具有足够的空间来设置注射器60。
请一并参阅图5,所示为本申请一实施例中注射器设置于注射泵的示意图。本实施例中,注射器60包括注射器本体602、设置于注射器本体602一端的凸缘604及活塞柄606,其中,注射器本体602内中空,用于收容活塞柄606,活塞柄606可在注射器本体602的径向方向移动。在将注射器60设置于注射泵10内时,用户可转动夹柄机构118至第二状态,以将注射器本体602压装于注射泵的泵主体110上,注射器50的凸缘604收容于泵主体110的收容槽116,活塞柄606与推动块1140之间的距离为预设距离d(示于图6)。
本实施例中,泵门112内可设置有位置传感器164,处理器150通过设置于泵门112内的第一位置传感器确定泵门112的状态,其中,泵门112的状态包括打开状态及关闭状态。如图2所示,处理器150可通过设置于第一位置传感器确定泵门112处于打开状态。请一并参阅图6,所示为本申请一实施例中注射泵的泵门被关闭的状态示意图。如图6所示,处理器150可通过第一位置传感器确定泵门112处于关闭状态。
本实施例中,夹柄机构118内设置有第二位置传感器,在将设置于注射泵10内的注射器60压装于注射泵10的泵主体110上时,夹柄机构118处于第二状态,此时,第二位置传感器可传输反馈信号。因此,处理器150可通过第二位置传感器检测注射器60是否设置于注射泵10内。例如,当注射器60设置于注射泵10内时,夹柄机构118将注射器本体602固定于泵主体110上,且第二位置传感器可输出反馈信号。如此,处理器150可确注射器60的注射器本体602压装于注射泵10的泵主体110上。在其他实施例中,夹柄机构118内可设置有压力传感器,即在注射器60压装于注射泵10的泵主体110上时,压力传感器可与注射器60接触,进而产生具有压力信息的反馈信号。处理器150亦可根据接收到的具有压力信息的反馈信号确定是否将设置于注射泵10内的注射器60压装于注射泵10的泵主体110上。
本实施例中,收容槽116内设置有第三位置传感器。在注射器60设置于注射泵10内时,注射器60的凸缘604收容于收容槽116内,此时,第三位置传感器亦可输出反馈信号。如此,当处理器150接收到第三位置传感器输出的反馈信号时,处理器150可确注射器60的凸缘604收容于收容槽116。
进而,处理器150可根据第一位置传感器检测泵门112的状态,还可根据第二位置传感器及第三位置传感器检测注射器60的设置状态。本实施例中,当第二位置传感器及第三位置传感器均传输反馈信号至处理器150时,处理器150可确定注射器60的设置状态正常;当处理器150没有接收到第二位置传感器及第三位置传感器中任一传感器所传输反馈信号时,处理器150可确定注射器60的设置状态异常。例如,当处理器150接收到第二位置传感器传感器传输的反馈信号而没有接收到第三位置传感器传输的反馈信号时,表示注射器60的凸缘604收容于收容槽116内,进而检测到注射器60的设置状态异常;当处理器150接收到第三位置传感器传感器传输的反馈信号而没有接收到第二位置传感器传输的反馈信号时,表示用户没有转到夹柄机构118至第二状态,夹柄机构118并没有将将注射器本体602固定于泵主体110上,进而处理器150亦可检测到注射器60的设置状态异常。处理器150在确定注射器60的设置状态异常时,控制显示屏160输出注射器60的设置状态异常的提示信息,处理器150还可通过灯光控制器148控制灯光组件168输出注射器60的设置状态异常的提示信息。
在一实施例中,若泵门112处于关闭状态且注射泵10内未设置有注射器60,注射泵10可处于关机状态或待机状态,若用户使用注射泵10来执行注射器60的输注任务,用户需要打开注射泵10的泵门112。在处理器150通过第一位置传感器检测到泵门112被打开时,处理器150控制注射泵10上电或进行开机操作,使得注射泵10处于开机状态。在用户设置注射器60期间(即处理器150检测到泵门112被打开至检测到泵门112被关闭的时间段内),注射泵10可进行自检操作,以检测注射泵10的设备状态。其中,注射泵10的自检操作包括但不限于声音自检、处理器自检、外部存储装置自检、报警灯自检、电源自检以及传感器自检。在进行声音自检时,处理器150可通过音频电路124控制扬声器154发出声响,并可通过录音装置确定声音自检是否通过;若处理器通过录音装置接收扬声器154发出声响,则可确定声音自检已通过,否则,表示注射泵10的设备状态异常。在进行处理器自检时,处理器150可运行存储器104内预设的程序,并确定运行预设的程序后得到的结果是否为预设结果;若对待预设的程序后得到的结果为预设结果时,则可确定处理器自检已 通过,否则,表示注射泵10的设备状态异常。此外,处理器150亦可对外部存储装置、灯光组件168、电源系统106以及多个传感器进行检测。当每一自检操作均通过时,可确定注射泵10的设备状态正常;在存在至少一个自检操作未通过时,则确定注射泵10的设备状态异常,并可通过显示屏160或灯光组件168输出设备状态异常的提示信息。
由于现有的技术方案可能会在设置注射器60于注射泵10之前执行自检操作,即在注射泵10完成自检操作之后再打开泵门112并将注射器60设置于注射泵10中,进而在一定程度上增加了输注任务准备阶段(或输注操作准备阶段)的时间。本实施例中,在泵门112被打开时,注射泵10进行开机动作,并在设置注射器60于注射泵10的过程中同时执行自检操作,即通过将注射泵10的自检操作与注射器60的设置进行并行处理,有利于减少输注任务准备阶段的时间。
在其他实施例中,注射泵10可包括开机按键(包括但不限于实体按键或其他类型的按键),在开机按键被触发时,用户可打开泵门112,以将注射器60设置于注射泵10中。之后,注射泵10亦在设置注射器60于注射泵10的过程中同时执行自检操作,亦可达到减少输注任务的时间的目的。
步骤143,在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常时,控制所述显示屏显示输液参数设置界面。
本实施例中,在处理器150检测到泵门112被关闭且注射器60设置于注射泵10中的设置状态正常,处理器150可控制设置于泵门112上的显示屏160显示输液参数设置界面510,其中,输液参数设置界面510包括输液参数设置项,输液参数设置项用于呈现一个或多个输液参数内容,包括但不限于输液速度、输液量等输液参数内容。当泵门112被关闭且注射器60设置于注射泵10中的设置状态正常时,推拉机构114的推动块1140与活塞柄606之间具有预设距离d,因此,驱动机构133控制推拉机构114启动输注操作时,驱动机构133需要将推动块1140朝向活塞柄606的预设距离d后,使得推动块1140与活塞柄606相抵住(或者相接触),之后,处理器150再根据设置的输液参数内容进行输注动作(或输注操作)。由于现有的技术方案可能会在推动块1140与活塞柄606相抵住之后,再控制显示屏160显示输液参数设备界面510,而推动块1140移动预设距离与活塞柄606相抵时需要一定的时间,如此,亦会使得输注准备阶段的时间增加。
请一并参阅图7,所示为本申请一实施例中推拉机构抵住活塞柄的状态示意图。本实施例中,在注射器60在注射泵10中的设置状态正常时,处理器150 在控制显示屏160显示输液参数设置界面510的同时,处理器150驱动驱动机构133以第一电机转速动作,带动推进机构114以朝向注射器60的活塞柄606的方向运动,驱动机构133在以第一电机转速动作预设时间后推进机构114抵住606活塞柄。如此,用户在通过输液参数设备界面510进行输液参数设备的同时控制推拉机构114的动作,如此,亦有利于减少输注操作的时间。
步骤145,根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动。
本实施例中,当推进机构114抵住606活塞柄后,注射泵10可进入启动输注操作阶段,处理器150可根据至少一个输液参数内容驱动驱动机构133以第二电机转速运动,控制注射器60的活塞柄606与注射器本体602发生相对运动,以使注射器60内的液体按照输液方向移动。
在本实施例中,泵门112上可设置有多个显示屏160,例如,设置有第一显示屏及第二显示屏,其中,第一显示屏用于显示输液参数设置界面510,第二显示屏用于显示功能操作界面512。如图7所示,功能操作界面512包括进度条显示区518、菜单按键区514及开关按键区516。在驱动机构133驱动推拉机构114进行输注操作时,表示注射泵10正在进行输注操作,此时,处理器150可控制进度条显示区518具有第一颜色信息(如绿色);在输注操作完成时,处理器150可控制进度条显示区518具有第二颜色信息(如红色);当注射泵10没有进行输注操作且注射泵10中没有设置注射器60时,处理器150可控制进度条显示区518具有第三颜色信息(如灰色)。
用户可通过触发菜单按键区514来对输液参数设备界面510内的内容进行设置或操作,并可确定是否启动输注操作。例如,用户在输液参数设备界面510进行设置时,处理器150用于检测用户在输液参数设置界面510上的触发事件,并基于所述触发事件调整输液参数内容。在驱动机构133以第一电机转速驱动推拉机构114移动预设距离d后接触活塞柄606时,若用户还在调整输液参数内容,此时,驱动机构133可暂停驱动推拉机构114,并在用户设置完成且启动输注指令后,处理器150再根据输液参数内容驱动驱动机构133进行运动,以启动输注操作。本实施例中,输注指令为用户在设置输液参数内容后触发启动按键时产生的,或者启动输注指令可由Dock发送。例如,在Dock中可能连接有多个注射泵,多个注射泵可用于按顺序执行多个药物的注射操作。Dock可根据多个注射泵的输注操作的顺序来发送启动输注指令至对应的注射泵。在检测到第一位置的注射泵的输注操作完成或即将完成时,Dock可发送启动输注指令至输注操作的顺序位于第一位置后的第二位置的注射泵,进而使得位于第二位 置的注射泵在接收到Dock所发送的启动输注指令后执行启动输注操作。用户可通过触发开关按键区516来完成注射泵10的开机、关机或待机动作。在一实施例中,推动块1140上可设置压力传感器,如此,在推动志1140块住活塞柄606时,设置于推动块1140上的压力传感器可输出具有压力信息的反馈信号至处理器150,进而使得处理器150在确定接收到设置于推动块1140上的压力传感器所传输的反馈信号时,可确定推动块1140与活塞柄606相抵住。如此,处理器150在接收到第二位置传感器、第三位置传感器及设置于推动块1140上的压力传感器所输出的反馈信号时,在用户设置完输液参数内容后接收到启动输注指令时,处理器150可根据设置的输液参数内容来控制驱动机构133的第二电机转速,以继续执行输注操作。
请一并参阅图8,所示为本申请一实施例中注射泵启动输注操作时的示意图。本实施例中,推拉机构114用以夹持注射器60的活塞柄606。注射泵10中的处理器150发出转速或者位置等指令,通过动力驱动电路130驱动动力设备(例如驱动机构133),驱动机构133经减速机构驱动丝杆135和丝母137,将驱动机构133的旋转运动转化为丝母137的直线运动,丝母137与注射泵10的连接杆1142相连,连接杆1142与推动块1140连接,推动块1140可推动配套的注射器60的活塞柄660进行注射输液,通过驱动机构133的旋转速度(如第二电机转速),就可调整其对配套的注射器60的推进速度,从而调整所给的输注剂量和输注速度。
在一实施例中,注射泵10在开机时或者是在更换注射器60期间,处理器150可在第一显示屏显示装管指引界面,包括但不限于注射器60的设置方向、设置时需注意的事项等内容,以方便用户准确地进行注射器60的设置。在其他实施例中,处理器150可在检测注射器60在注射泵10中的设置状态被检测为正常时或之前,控制第一显示屏显示装管指引界面。
在一实施例中,泵门112上设置有一个显示屏160,如此,输液参数设置界面510及功能操作界面512可设置于显示屏160的不同分区内。
在一实施例中,在检测泵门112的状态及注射器60在注射泵10中的设置状态之后,处理器150可确定注射器10内液体的预置量信息。例如,处理器150在检测到泵门112被打开至泵门112被关闭的期间确定注射器10内液体的预置量信息。其中,处理器150可通过传感器检测注射器60的外径信息及注射器60内液体在注射器60的活塞柄606的长度方向的长度信息,进而基于外径信息及长度信息确定注射器60内液体的预置量信息。在其他实施例中,用户亦可在输液参数设置界面510内设置预置量信息。
在执行输注操作过程中,注射器60内的液体逐渐减少,进而,处理器150还可根据驱动机构133的动作确定已输注的液体体积信息及注射器60内液体的剩余的液体体积信息。处理器150还可根据剩余的液体体积信息及输液参数内容确定输注进度信息,如确定剩余的输注时间。处理器150还控制显示屏160内显示输注进度信息。
目前注射泵在启动输注之前的准备工作流程中均采用串行设计,开机之后会进行开机自检,并在开机自检成功之后才开始识别注射器状态;用户打开泵门装注射器,会将推拉机构拉开,并等到注射器在注射泵内设置成功,并且推拉机构与活塞柄夹持成功之后,才会在屏幕上设置输液参数设置界面以供用户编辑或者确认。中间仅推拉机构从最远处到与活塞柄夹持的时间就可以能需要数十秒,这个过程十分漫长,且用户只能等待,十分不合理。
上述注射泵控制方法通过将注射泵的自检操作与注射器的设置进行并行处理,有利于减少输注任务的时间的花费。另外,注射泵在检测到泵门被关闭且注射器在注射泵中的设置状态正常,控制显示屏显示输液参数设置界面,如此亦可减少在等待推拉机构运行预设时间后抵住活塞柄后再显示输液参数设置界面所带来的输注时间的浪费的不足。上述注射泵控制方法检测到并可在通过输液参数设备界面进行输液参数进行输入和/或确认的同时控制推拉机构的动作,如此,亦有利于减少输注操作的时间。并且为了确保注射泵的使用安全,只有在推拉机构与活塞柄夹持正确之后,且注射泵的输液参数设置完成之后,用户才能启动输注,既有效缩短了用户的等待时间,并且无损注射泵的使用安全。
在上述实施例中,对各个实施例的描述都各有侧重,某个实施例中没有详述的部分,可以参见其他实施例的相关描述。
在本申请所提供的几个实施例中,应该理解到,所揭露的装置,可通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如所述单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性或其它的形式。
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。
另外,在本申请各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。上述集成的单元既可以采用硬件的形式实现,也可以采用软件功能单元的形式实现。
以上对本申请实施例进行了详细介绍,本文中应用了具体个例对本申请的原理及实施方式进行了阐述,以上实施例的说明只是用于帮助理解本申请的方法及其核心思想;同时,对于本领域的一般技术人员,依据本申请的思想,在具体实施方式及应用范围上均会有改变之处,综上所述,本说明书内容不应理解为对本申请的限制。

Claims (30)

  1. 一种注射泵控制方法,应用于注射泵,其特征在于,所述注射泵用于与注射器配套使用,所述注射泵包括泵主体、驱动机构、显示屏及泵门,所述泵门转动设置于所述泵主体上,所述注射泵控制方法包括:
    检测所述泵门的状态及所述注射器在所述注射泵中的设置状态;
    在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常时,控制所述显示屏显示输液参数设置界面,其中,所述输液参数设置界面包括输液参数设置项,所述输液参数设置项用于呈现一个或多个输液参数内容;
    根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动。
  2. 如权利要求1所述的注射泵控制方法,其特征在于,所述注射泵还包括推进机构,所述控制所述显示屏显示所述输液参数设置界面的同时,还包括:
    驱动所述驱动机构,控制所述推进机构以朝向所述注射器的活塞柄的方向运动。
  3. 如权利要求2所述的注射泵控制方法,其特征在于,所述注射器的活塞柄与所述夹持组件之间在所述活塞柄的长度方向上间隔预设距离,所述驱动所述驱动机构,控制所述推进机构以朝向所述注射器的活塞柄的方向运动,包括:
    驱动所述驱动机构以第一电机转速动作,带动所述推进机构以朝向所述注射器的活塞柄的方向运动,其中,所述驱动机构在以第一电机转速动作预设时间后所述推进机构抵住所述活塞柄;
    所述根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动,包括:
    根据至少一个所述输液参数内容驱动所述驱动机构以第二电机转速运动;
    控制所述注射器的活塞柄与所述注射器本体发生相对运动,以使所述注射器内的液体按照输液方向移动。
  4. 如权利要求1所述的注射泵控制方法,其特征在于,所述检测所述泵门的状态及所述注射器在所述注射泵中的设置状态之后,还包括:
    在检测到所述泵门被打开且检测到所述泵门被关闭,并在所述泵门被打开至所述泵门被关闭的期间,检测所述注射泵的设备状态;
    所述在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常时,控制所述显示屏显示输液参数设置界面,包括:
    在检测到所述泵门被关闭后,若检测到所述注射泵的设备状态正常且所述注射器在所述注射泵中的设置状态正常,控制所述显示屏显示所述输液参数设置界 面。
  5. 如权利要求4所述的注射泵控制方法,其特征在于,所述检测所述注射泵的设备状态,包括:
    执行声音自检、处理器自检、外部存储装置自检、报警灯自检、电源自检以及传感器自检中的至少一个来确定所述注射泵的设备状态。
  6. 如权利要求1所述的注射泵控制方法,其特征在于,所述注射泵控制方法还包括:
    检测用户在所述输液参数设置界面上的触发事件;
    基于所述触发事件调整所述输液参数内容。
  7. 如权利要求1所述的注射泵控制方法,其特征在于,所述检测所述泵门的状态及所述注射器在所述注射泵中的设置状态之后,还包括:
    在检测到所述泵门被打开且所述注射泵内未设置有注射器时,控制所述注射泵进行开机操作。
  8. 如权利要求1所述的注射泵控制方法,其特征在于,所述检测所述泵门的状态及所述注射器在所述注射泵中的设置状态之后,还包括:
    在检测所述注射器在所述注射泵中的设置状态被检测为正常时或之前,控制在所述显示屏内显示装管指引界面。
  9. 如权利要求1所述的注射泵控制方法,其特征在于,所述注射泵包括设置于目标位置处的传感器,所述检测所述泵门的状态及所述注射器在所述注射泵中的设置状态之后,还包括:
    在检测到所述泵门由关闭状态转换为打开状态时,基于所述传感器确定所述注射器的设置状态。
  10. 如权利要求9所述的注射泵控制方法,其特征在于,所述传感器包括第一传感器及第二传感器,所述注射泵包括收容槽及设置于所述泵主体上的夹柄机构,所述收容槽内设置有所述第一传感器,所述第二传感器设置于所述夹柄机构上;在所述注射器设置于所述注射泵内时,若所述注射器本体上的凸缘收容于所述注射泵的泵主体上的收容槽内且所述夹柄机构将所述注射器本体压装于所述注射泵的泵主体上,所述第一传感器输出第一反馈信号,所述第二传感器输出第二反馈信号;所述基于所述传感器确定所述注射器的设置状态,包括:
    在接收到所述第一反馈信号及所述第二反馈信号时确定所述注射器的设置状态正常。
  11. 如权利要求10所述的注射泵控制方法,其特征在于,所述传感器包括第三传感器,所述夹持组件包括推动块,所述第三传感器设置于所述推动块上, 在所述注射泵的夹持组件抵住所述注射器的活塞柄时,所述推动块与所述活塞柄相接触,所述第三传感器输出第三反馈信号,所述根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动之前,还包括:
    判断是否接收到所述第一反馈信号、第二反馈信号及第三反馈信号;
    当所述处理器接收到所述第一反馈信号、第二反馈信号及第三反馈信号时,根据至少一个所述输液参数内容驱动所述驱动机构进行运动,以使所述注射器内的液体按照输液方向移动。
  12. 如权利要求1所述的注射泵控制方法,其特征在于,所述检测所述泵门的状态及所述注射器在所述注射泵中的设置状态之后,还包括:
    确定所述注射器内液体的预置量信息。
  13. 如权利要求12所述的注射泵控制方法,其特征在于,所述确定所述注射器内液体的预置量信息,包括:
    检测所述注射器的外径信息及所述注射器内液体在所述注射器的活塞柄的长度方向的长度信息;
    基于所述外径信息及所述长度信息确定所述注射器内液体的预置量信息。
  14. 如权利要求13中所述的注射泵控制方法,其特征在于,所述注射泵控制方法还包括:
    根据所述驱动机构的动作确定所述注射器内液体的剩余的液体体积信息;
    根据剩余的液体体积信息及所述输液参数内容确定输注进度信息;
    控制所述显示屏内显示所述输注进度信息。
  15. 一种注射泵,其特征在于,所述注射泵用于与注射器配套使用,所述注射泵包括泵主体、驱动机构、处理器、显示屏及泵门,所述泵门转动设置于所述泵主体上;所述处理器用于在检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常,控制所述显示屏显示输液参数设置界面,其中,所述输液参数设置界面包括输液参数设置项,所述输液参数设置项用于呈现一个或多个输液参数内容;所述处理器还用于根据至少一个所述输液参数内容驱动所述驱动机构的运动,以使所述注射器内的液体按照输液方向移动。
  16. 如权利要求15所述的注射泵,其特征在于,所述注射泵还包括推进机构,所述处理器检测到所述泵门被关闭且所述注射器在所述注射泵中的设置状态正常,并在控制所述显示屏显示所述输液参数设置界面的同时,所述处理器还驱动所述驱动机构,控制所述推进机构以朝向所述注射器的活塞柄的方向运动。
  17. 如权利要求16所述的注射泵,其特征在于,所述处理器检测到所述泵 门被关闭且所述注射器在所述注射泵中的设置状态正常,所述注射器的活塞柄与所述夹持组件之间在所述活塞柄的长度方向上间隔预设距离,所述处理器在控制所述显示屏显示输液参数设置界面的同时,所述处理器驱动所述驱动机构以第一电机转速动作,带动所述推进机构以朝向所述注射器的活塞柄的方向运动,所述驱动机构在以第一电机转速动作预设时间后所述推进机构抵住所述活塞柄;所述处理器还根据至少一个所述输液参数内容驱动所述驱动机构以第二电机转速运动,控制所述注射器的活塞柄与所述注射器本体发生相对运动,以使所述注射器内的液体按照输液方向移动。
  18. 如权利要求15所述的注射泵,其特征在于,所述处理器还用于检测到所述泵门被打开和检测到所述泵门被关闭,并在所述泵门被打开至所述泵门被关闭的期间,检测所述注射泵的设备状态;
    在检测到所述泵门被关闭后,所述处理器还用于在确定所述注射泵的设备状态正常且所述注射器在所述注射泵中的设置状态正常时,控制所述显示屏显示所述输液参数设置界面。
  19. 如权利要求18所述的注射泵,其特征在于,所述处理器用于执行声音自检、处理器自检、外部存储装置自检、报警灯自检、电源自检以及传感器自检中的至少一个来确定所述注射泵的设备状态。
  20. 如权利要求15所述的注射泵,其特征在于,所述处理器用于检测用户在所述输液参数设置界面上的触发事件,并基于所述触发事件调整所述输液参数内容。
  21. 如权利要求15所述的注射泵,其特征在于,所述处理器用于在检测到所述泵门被打开且所述注射泵内未设置有注射器,控制所述注射泵进行开机操作。
  22. 如权利要求15所述的注射泵,其特征在于,所述处理器还用于在检测所述注射器在所述注射泵中的设置状态被检测为正常时或之前,控制在所述显示屏内显示装管指引界面。
  23. 如权利要求15-22中任一项所述的注射泵,其特征在于,所述注射泵包括设置于目标位置处的传感器,所述处理器基于所述传感器确定所述注射器的设置状态。
  24. 如权利要求23所述的注射泵,其特征在于,所述传感器包括第一传感器及第二传感器,所述注射泵包括收容槽及设置于所述泵主体上的夹柄机构,所述收容槽内设置有所述第一传感器,所述第二传感器设置于所述夹柄机构上;在所述注射器设置于所述注射泵内时,若所述注射器本体上的凸缘收容于所述注射泵的泵主体上的收容槽内且所述夹柄机构将所述注射器本体压装于所述注射泵 的泵主体上,所述第一传感器输出第一反馈信号,所述第二传感器输出第二反馈信号;所述处理器在接收到所述第一反馈信号及所述第二反馈信号时确定所述注射器的设置状态正常。
  25. 如权利要求24所述的注射泵,其特征在于,所述传感器还包括第三传感器,所述夹持组件包括推动块,所述夹持组件的推动块上设置有所述第三传感器,在所述注射泵的夹持组件抵住所述注射器的活塞柄时,所述推动块与所述注射器的活塞柄相接触,所述第三传感器输出第三反馈信号,所述处理器在接收到所述第一反馈信号、第二反馈信号及第三反馈信号,启动输注操作,以根据至少一个所述输液参数内容驱动所述驱动机构进行运动。
  26. 如权利要求23所述的注射泵,其特征在于,所述处理器用于确定所述注射器内液体的预置量信息。
  27. 如权利要求26所述的注射泵,其特征在于,所述处理器用于检测所述注射器的外径信息及所述注射器内液体在所述注射器的活塞柄的长度方向的长度信息,所述处理器基于所述外径信息及所述长度信息确定所述注射器内液体的预置量信息。
  28. 如权利要求27中所述的注射泵,其特征在于,所述处理器用于根据所述驱动机构的动作确定所述注射器内液体的剩余的液体体积信息,并根据剩余的液体体积信息及所述输液参数内容确定输注进度信息,所述处理器还控制所述显示屏内显示所述输注进度信息。
  29. 一种注射泵系统,其特征在于,所述注射泵系统包括注射器及如权利要求15至28中任一项所述的注射泵。
  30. 一种计算机可读存储介质,存储有计算机指令,其特征在于,所述计算机指令被处理器执行时实现如权利要求1至14中任一项所述的注射泵控制方法。
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