CN117653486A - Portable critical illness transports first aid equipment - Google Patents

Abstract

The invention discloses movable critical transport emergency equipment. The method is characterized in that: including host computer body, support and have the chassis that removes the wheel, the host computer body passes through the leg joint chassis, and the host computer body is equipped with medical gas terminal, strong electric socket, light current interface, storage, is equipped with oxygen supply device, negative pressure device and UPS power supply unit on support and/or the chassis, and the support is equipped with interfacing apparatus I, and the chassis can remove to the chassis below of transporting the bed to be connected fixedly through interfacing apparatus I with the interfacing apparatus II who establishes at transporting the bed tip, the host computer body still includes one or more than two of breathing machine subassembly, electrocardiograph guardianship subassembly, defibrillation subassembly and at least one display device. The invention has the advantages of being connected with the transfer bed and being used along with the movement of the bed, being used as emergency equipment independently, meeting the clinical transfer requirement by the structural design, being convenient for movement and management, medical care operation and use, and the like.

Description

Portable critical illness transports first aid equipment

Technical Field

The invention relates to movable critical transport emergency equipment, and belongs to the field of medical transport equipment.

Background

The electrocardiograph monitor, the breathing machine, the oxygen supply, the suction, the liquid medicine infusion and the defibrillator are medical conventional life support treatment equipment, and are indispensable functional associated equipment in the critical treatment process.

Although some technical schemes are proposed to solve the problems, the technical scheme has a plurality of defects, such as that various medical devices are integrally arranged on the transfer bed, the volume, the weight and the purchase cost of the transfer bed are increased, the various medical devices integrally arranged on the transfer bed are only limited to critical diseases to be used in the transfer process, and the medical devices cannot exert corresponding function when common patients are transferred and are idle, so that medical resource waste is caused.

Disclosure of Invention

Aiming at the technical problems, the invention provides the movable critical transport emergency equipment, which integrates the functions of electrocardiograph monitoring, auxiliary/alternative respiration, cardiac defibrillation, oxygen output, negative pressure suction, liquid medicine infusion and the like, can be connected with a transport bed and can be used along with the movement of the bed, and can be independently used as emergency equipment, and the structural design of the movable critical transport emergency equipment meets the clinical transport requirement and is convenient for movement and management and medical care operation.

The aim of the invention can be achieved by the following technical solutions:

a mobile critical illness transportation first-aid device, characterized by: including host computer body, support and have the chassis of removing the wheel, the host computer body passes through the leg joint the chassis, the host computer body is equipped with medical terminal, strong electric socket, weak current interface, accomodates the portion, be equipped with oxygen supply device, negative pressure device and UPS power supply unit on support and/or the chassis, the support is equipped with interfacing apparatus I, the chassis is movable to the chassis below of transporting the bed, and through interfacing apparatus I with establish interfacing apparatus II connection fixed of transporting the bed tip, the host computer body still includes one or more than two and at least one display device of breathing machine subassembly, electrocardiograph guardianship subassembly, defibrillation subassembly.

In the technical scheme of the invention, the bracket and/or the chassis below the main machine body are provided with the equipment box, and one or more than two of the oxygen supply device, the negative pressure device and the UPS power supply device are arranged in the equipment box.

In the technical scheme of the invention, the negative pressure device and the UPS power supply device are respectively arranged on the equipment box, and the oxygen supply device is fixed on the chassis positioned at the rear side of the bracket through the fixed shield.

In the technical scheme of the invention, the support or the main machine body is provided with a push-pull handrail.

In the technical scheme of the invention, the docking device II is arranged at the end part of the bed tail of the transfer bed, and the chassis moves from the end part of the bed tail to the lower part of the underframe of the transfer bed and is connected with the end part of the bed tail of the transfer bed through the docking device I and the docking device II.

According to the technical scheme, the butt joint device I and the butt joint device II are fixed through the pin shaft, and the pin shaft is locked in a matched mode through the fixed block, the locking sliding block and the spring which are arranged at one end of the butt joint device I.

In the technical scheme of the invention, the chassis is of a T-shaped structure.

In the technical scheme of the invention, the breathing machine assembly comprises a breathing machine device, a breathing function external port and corresponding control keys, wherein the breathing machine device and the main body are in a fixed connection or detachable connection structure, the breathing machine device is of an invasive/noninvasive breathing structure, and the breathing machine device comprises an air-oxygen mixing module, an air suction module, an air expiration module, a monitoring module, a control module, an air supply driving device, an air inlet, an air outlet and a constant-temperature humidifying device.

In the technical scheme of the invention, the electrocardiograph monitoring assembly comprises an electrocardiograph monitoring main control module, an electrocardiograph monitoring functional module, an electrocardiograph monitoring external port and corresponding control keys, wherein the electrocardiograph monitoring main control module and the electrocardiograph monitoring functional module are integrally or separately constructed in the main machine body, the electrocardiograph monitoring main control module and the electrocardiograph monitoring functional module are fixedly connected or detachably connected with the main machine body, and the electrocardiograph monitoring functional module comprises one or more than two structures of an electrocardiograph module, a heart rate module, a noninvasive/invasive blood pressure module, a respiration module, a blood oxygen saturation module, a body temperature module and a noninvasive continuous blood pressure module.

In the technical scheme of the invention, the defibrillation component comprises a defibrillation device and a defibrillation control external connection area, and the defibrillation device is fixedly or detachably connected to the main body.

In the technical scheme of the invention, the main body further comprises one or more than two of an oxygen pressure and flow monitoring device, a UPS electric quantity monitoring device and an infusion support, and the infusion support is detachably arranged on the main body.

In the technical scheme of the invention, the containing part is configured to contain the opening and closing door or the drawer.

In the technical scheme of the invention, the bracket is provided with a lifting device, and the lifting device is an electric or pneumatic or hydraulic or manual lifting structure.

In the technical scheme of the invention, the oxygen supply device is of an oxygen bottle structure or an oxygen bag/box structure or an oxygen generator structure.

The invention is an improvement to the prior art, and has the advantages and beneficial effects that:

1. this first aid equipment can integrated installation oxygen supply unit, negative pressure device, defibrillation subassembly, UPS power supply unit, medical gas terminal, strong electric socket, light current interface, breathing machine subassembly, electrocardiograph guardianship subassembly, display device, effectively solves respectively in the transportation process of critical relief and dispersedly stacks, hang the dress in transporting the bed, and the external pipeline is crisscross in disorder, unexpected collision falls scheduling problem, improves safety, stability to the first aid equipment use in the transportation of critical relief, is convenient for daily use and management.

2. The emergency equipment integrates necessary life support treatment functions for the treatment and transportation of critically ill patients, one emergency equipment can be provided with a plurality of transportation beds to be used, the emergency equipment can be used along with the movement of the beds through the quick connection of the docking device and the transportation beds, and can be separated from the transportation beds to be used as independent equipment for moving among various sick areas when the transportation beds are not required, so that the utilization rate of the emergency equipment is improved, the waste of medical resources is avoided, and the purchase and use cost of hospitals can be effectively reduced.

3. When the emergency equipment is connected with the transferring bed for use, the space of the upper part, the lower part and the bottom part in the range of the transferring bed body is fully utilized, so that the emergency equipment only extends for a very small length or width when being connected with the transferring bed, and can meet the use requirements (such as corners, an elevator room and the like) of various areas of a hospital.

4. The first-aid equipment is provided with the containing part, and the containing part can be used for placing accessories such as auxiliary/alternative respiration, electrocardiographic monitoring, cardiac defibrillation and the like, so that the convenience of use and management is further improved.

5. The emergency equipment is provided with an oxygen pressure flow monitoring device and a UPS electric quantity monitoring device, can monitor the reserve quantities of oxygen and a power supply in real time, and provides real-time display and reminding so as to maintain and replace in time.

Drawings

Fig. 1 is a front view of the structure of embodiment 1 of the present invention.

Fig. 2 is a schematic view of the structure of fig. 1 in a partial cross section.

FIG. 3 is a schematic view of the B-direction structure of FIG. 1

Fig. 4 is a schematic perspective view of the structure of fig. 3.

Fig. 5 is a schematic view of the cross-sectional structure of the line C-C in fig. 1.

Fig. 6 is a schematic view of the D-direction structure in fig. 1.

FIG. 7 is a view showing the connection of embodiment 1 to a transfer bed.

Fig. 8 is a schematic view of the E-direction structure in fig. 7.

FIG. 9 is a partially enlarged schematic view of the connection state of the docking device I and the docking device II according to the present invention.

Fig. 10 is a schematic view of the cross-sectional structure of the line F-F in fig. 9.

Fig. 11 is a schematic diagram of the G-direction structure in fig. 9.

Fig. 12 is a schematic view of the cross-sectional structure of the H-H line in fig. 11.

Fig. 13 is a schematic structural view of embodiment 2 of the present invention.

Fig. 14 is a schematic structural view of embodiment 3 of the present invention.

Fig. 15 is a schematic diagram of the I-direction structure in fig. 14.

FIG. 16 is a schematic view showing the structure of embodiment 4 of the present invention.

Fig. 17 is a schematic view of the J-direction structure of fig. 16.

Fig. 18 is a schematic structural view of embodiment 5 of the present invention.

The drawings are marked with the following description: the device comprises a 1-main body, a 2-oxygen pressure and flow monitoring device, a 3-medical terminal, a 4-respiratory function external port, a 5-push-pull handrail, a 6-support, a 7-docking device I, an 8-equipment box, a 9-chassis, a 10-moving wheel, an 11-electrocardiograph monitoring external port, a 12-defibrillation operation external area, a 13-infusion support, a 14-strong electric socket, a 15-display device, a 16-containing part, a 17-oxygen supply device, a 18-fixed shield, a 19-air storage tank, a 20-UPS power supply device, a 21-negative pressure device, a 22-electrocardiograph monitoring main control module, a 23-breathing machine device, a 24-containing opening and closing door, a 25-UPS electric quantity monitoring device, a 26-defibrillation device, a 27-electrocardiograph monitoring function module, a 28-transfer bed, a 29-docking device II, a 30-pin shaft, a 31-locking slide block, a 32-spring, a 33-fixed block and a 34-lifting device.

Detailed Description

The invention will be described in detail below with reference to the attached drawings and specific examples:

fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18 illustrate embodiments of the present invention. The composition is as follows: the device is formed by assembling a main body 1, an oxygen pressure and flow monitoring device 2, a medical terminal 3, a breathing function external port 4, a push-pull handrail 5, a support 6, a docking device I7, an equipment box 8, a chassis 9, a movable wheel 10, an electrocardiograph monitoring external port 11, a defibrillation operation external area 12, an infusion support 13, a strong electric socket 14, a display device 15, a storage part 16, an oxygen supply device 17, a fixed shield 18, an air storage tank 19, a UPS power supply device 20, a negative pressure device 21, an electrocardiograph monitoring main control module 22, a breathing machine device 23, a storage opening and closing door 24, a UPS electric quantity monitoring device 25, a defibrillation device 26, an electrocardiograph monitoring functional module 27, a transfer bed 28, a docking device II 29, a pin shaft 30, a locking slide block 31, a spring 32, a fixed block 33, a lifting device 34 and a connecting component and a fastener.

The specific embodiment has the structural characteristics that:

a mobile critical illness transportation first-aid device, characterized by: including host computer body 1, support 6 and have chassis 9 of removing wheel 10, the host computer body passes through the leg joint the chassis, the host computer body is equipped with medical terminal 3, strong electricity socket 14, weak current interface, storage 16, be equipped with oxygen supply unit 17, negative pressure device 21 and UPS power supply unit 20 on support and/or the chassis, the support is equipped with interfacing apparatus I7, the chassis is movable to the chassis below of transporting bed 28, and through interfacing apparatus I with establish interfacing apparatus II 29 connection fixed of transporting bed tip, the host computer body still includes one or more than two of breathing machine subassembly, electrocardiograph guardianship subassembly, defibrillation subassembly and at least one display device 15.

Fig. 1, 2, 3, 4, 5, and 6 show embodiment 1 of the present invention.

Including host computer body 1, support 6 and have chassis 9 of removing wheel 10, host computer body 1 one end passes through support 6 and connects chassis 9's one end and be located its top, and the connecting portion of support 6 one side and chassis 8 is equipped with equipment box 8, and UPS power supply unit 20, negative pressure device 21 are installed in equipment box 8, and oxygen supply unit 17 is the oxygen bottle structure to install on chassis 9 of support 6 opposite side through fixed guard shield 18, chassis 9 adopts "T" type structure, and support 6 upper end both sides are equipped with push-and-pull handrail 5 respectively, are equipped with connecting device I7 on support 6 one side between host computer body 1 and equipment box 8.

The medical air terminal 3, the strong electric socket 14 and a display device 15 are respectively arranged in the front direction of the main body 1, an oxygen pressure flow monitoring device 2 and a UPS electric quantity monitoring device 25 are arranged on the side direction of the main body, and an infusion support 13 is arranged at the top end of the main body.

The breathing machine device 23, the electrocardiograph monitoring main control module 22, the electrocardiograph monitoring functional module 27 and the defibrillation device 26 are integrally arranged in the inner cavity of the main machine body 1, the breathing function external connection port 4 of the breathing machine device 23, the electrocardiograph monitoring external connection port 11 of the electrocardiograph monitoring functional module 27 and the defibrillation control external area 12 of the defibrillation device 26 are respectively arranged in the front direction of the main machine body 1, corresponding control keys for the breathing machine device 23 and the electrocardiograph monitoring main control module 22 are arranged in the front direction of the main machine body 1, the breathing function external connection port 4 comprises an air suction pipe interface, an air breathing pipe interface and the like, the electrocardiograph monitoring external connection port comprises ports required by connecting various vital sign parameter modules with parameter acquisition cables of the electrocardiograph monitoring external connection port, and the defibrillation control external area 12 is provided with defibrillation control keys, defibrillation indicator lamps, electrode slice interfaces and the like.

The electrocardiographic monitoring main control module 22 and the electrocardiographic monitoring functional module 27 are electrically connected and are separately constructed in the inner cavity of the main machine body 1, and vital sign parameters acquired by the electrocardiographic monitoring functional module 27 are processed by the electrocardiographic monitoring main control module 22.

The display device 15 may be used to simultaneously display or switch between displaying the corresponding dynamic graphics and indices acquired by the respiratory device 23, the electrocardiographic monitoring and control module 22, and the defibrillation device 26.

The inner cavity of the main body 1 is also provided with two storage parts 16, the top end of the main body 1 corresponding to the two storage parts 16 is respectively provided with a corresponding storage opening and closing door 24, the storage parts 16 can store accessories required by the breathing machine device 23, the electrocardiograph monitoring function module 27 and the defibrillation device 26, and the accessories comprise, but are not limited to, external inhalation/exhalation pipelines required by the breathing machine device 23, parameter acquisition cables required by the electrocardiograph monitoring function module 27, electrode plates required by the defibrillation device 26 and the like.

The oxygen supply device 17 of oxygen bottle structure is connected with the medical terminal 3 and the breathing machine device 23 respectively through the pipeline, the medical terminal 3 of connecting the oxygen supply device 17 constitutes the oxygen output terminal, the negative pressure device 21 passes through the gas holder 19 of pipe connection setting in the equipment box 8, by gas holder 19 rethread pipe connection another medical terminal 3, make this medical terminal 3 constitute negative pressure suction terminal, the pipeline between oxygen pressure flow monitoring device 2 connecting the oxygen supply device 17 and the medical terminal 3 for real-time supervision and suggestion oxygen surplus of oxygen supply device 17, its suggestion can be screen display, sound, light etc..

The UPS power source device 20 is connected to the negative pressure device 21, the defibrillation device 26, the strong electric socket 14, the oxygen pressure flow monitoring device 2, and the UPS power monitoring device 25 through lines, where the UPS power monitoring device 25 is used for monitoring and prompting the power of the UPS power source device 20 in real time, and the prompting may be screen display, sound, light, etc.

The infusion support 13 is used for hanging infusion bottles/bags and infusion pumps, and the strong electric socket 14 is used for medical equipment such as infusion pumps which need external power supplies.

When connected to the transfer bed 28, the main body 1, the equipment box 8 and the chassis 9 thereof will be within the bed body of the transfer bed 28, the narrower end of the chassis 9 being in the shape of a "T" being more convenient for entering from the head or tail end of the transfer bed 28 below the chassis thereof.

The docking device II 29 is arranged on the underframe of the transfer bed 28 at the end part of the bed tail, as shown in fig. 7 and 8, when being connected with the transfer bed 28, one end of the chassis 9 can move to the lower part of the underframe of the transfer bed 28, the equipment box 8 is arranged below the bed surface of the transfer bed 28, the main body 1 is arranged above the bed surface of the transfer bed 28, the bracket 6 is abutted against the end of the bed tail of the transfer bed 28, and the main body 1, the equipment box 8 and the chassis 9 are all in the range of the bed body of the transfer bed 28.

Referring to fig. 9, 10, 11 and 12, the connection end of the docking device i 7 and the docking device ii 29 are in corresponding concave-convex connection structures, that is, the docking device i 7 has a V-shaped concave portion, the connection end of the docking device ii 29 is connected with a convex portion corresponding to the concave portion, after the connection end of the docking device i 7 and the convex portion are matched, the docking device i 9 and the convex portion penetrate through the connection end of the docking device i 7 and the docking device ii 29 through a pin shaft 30 to be fixed, one end of the docking device i 9, which is located at one end of the pin shaft 30, is provided with a relative fixing block 33 and a locking sliding block 31, the opposite end of the pin shaft 30, which is located at the opposite end of the fixing block 33 and the locking sliding block 31, is provided with a groove, the fixing block 33 and the locking sliding block 31 are clamped in the groove to lock the pin shaft 30, the locking sliding block 31 is provided with a spring 32, and the locking sliding block 31 is matched through the spring 32 to realize locking and unlocking functions.

Through embodiment 1, the emergency equipment simultaneously has the functions of oxygen output, negative pressure suction, liquid medicine infusion, auxiliary/alternative respiration, electrocardiograph monitoring, cardiac defibrillation and power supply, which are needed by critical rescue, and no additional independent electrocardiograph monitor, respirator and defibrillator are needed, the air source and power supply do not need external supply, and the functions are complete.

Fig. 13 shows embodiment 2 of the present invention.

The same parts of this embodiment as those of embodiment 1 will not be described in detail herein, in this embodiment, the main body 1 is provided with two display devices 15 in the forward direction, one display device 15 is used for displaying the relevant dynamic graphics and indexes acquired and processed by the respiratory device 23, and the other display device 15 is used for displaying the corresponding dynamic graphics and indexes acquired and processed by the electrocardiographic monitoring and control module 22 and the defibrillation device 26.

Fig. 14 and 15 show embodiment 3 of the present invention.

The same parts of this embodiment as those of embodiment 1 will not be described in detail herein, and as can be seen from the accompanying drawings, the main body 1 has an integrated electrocardiograph monitoring main control module 22 and electrocardiograph monitoring functional module 27, but not the ventilator device 23 and the defibrillator device 26, the electrocardiograph monitoring external port 11 and the corresponding control keys of the electrocardiograph monitoring functional module 27 are arranged in the forward direction of the main body 1, and a display device 15 is arranged in the forward direction of the main body 1 and is used for displaying the corresponding dynamic graphics and indexes collected and processed by the electrocardiograph monitoring main control module 22.

Fig. 16 and 17 show embodiment 4 of the present invention.

In this embodiment, the ventilator device 23 is integrally installed in the inner cavity of the main body 1, but the electrocardiograph monitoring main control module 22, the electrocardiograph monitoring functional module 27 and the defibrillation device 26 are not installed, the external breathing function port 4 of the ventilator device 23 and the corresponding control keys are arranged in the forward direction of the main body 1, and a display device 15 is installed in the forward direction of the main body 1 and is used for displaying the corresponding dynamic graphics and indexes acquired and processed by the ventilator device 23.

It should be noted that, in some embodiments, the defibrillation device 26 is integrally installed in the inner cavity of the main body 1, but the ventilator device 23, the electrocardiograph monitoring main control module 22 and the electrocardiograph monitoring functional module 27 are not installed, the defibrillation operation external connection area 12 is forward of the main body 1, and a display device 15 is installed forward of the main body 1 and is used for displaying corresponding dynamic graphics and indexes acquired and processed by the defibrillation device 26, so that the emergency equipment of the embodiment simultaneously has the functions of oxygen output, negative pressure suction, medical fluid infusion, cardiac defibrillation and power supply needed by critical rescue, and no external air source and power supply are needed to meet the configuration requirements of different users.

In an embodiment of the present invention, the ventilator device 23 is an invasive/noninvasive breathing structure, which is in a fixed connection structure or a detachable connection structure with the main body 1, and the ventilator device 23 includes, but is not limited to, an air-oxygen mixing module, an inspiration module, an expiration module, a monitoring module, a control module, an air supply driving device, an air inlet, an air outlet, and a constant temperature humidifying device configuration.

It should be understood that the ventilator device 23 and the related parameters are all related in the art, and those skilled in the art should be aware of the specific implementation structure, and will not be described herein.

In embodiments of the present invention, the electrocardiographic monitoring function module 27 includes, but is not limited to, one or more of an electrocardiographic module, a heart rhythm module, a heart rate module, a noninvasive/invasive blood pressure module, a respiration module, a blood oxygen saturation module, a body temperature module, and a noninvasive continuous blood pressure module.

In embodiments of the present invention, defibrillation device 26 is either an automatic external defibrillation configuration or a manual external defibrillation configuration, both of which are known in the art, and those skilled in the art will know how to implement the specific configuration of the application.

It should be noted that, in the embodiment in which the main body 1 is integrally provided with the electrocardiographic monitoring main control module 22 and the electrocardiographic monitoring functional module 27, the electrocardiographic monitoring main control module 22 and the electrocardiographic monitoring functional module 27 are integrally configured and installed in the inner cavity of the main body 1, and are in a fixed connection structure or a detachable connection structure with the main body 1, while in other embodiments, the electrocardiographic monitoring main control module 22 and the electrocardiographic monitoring functional module 27 are separately configured and installed in the inner cavity of the main body 1, and the electrocardiographic monitoring main control module 22 and the electrocardiographic monitoring functional module 27 are respectively fixedly and/or detachably connected to the main body 1.

It should be understood that the electrocardiographic monitoring main control module 22, the electrocardiographic monitoring functional module 27 and how to collect and process the relevant vital sign parameters are all of the prior art, and those skilled in the art should be aware of the specific implementation structure, and will not be described herein.

In the present embodiment, defibrillation device 26 is an automatic external defibrillation structure that is fixedly or removably attached to the interior cavity of main housing 1.

It should be understood that the defibrillation device 26 and the related parameters are all well known in the art, and those skilled in the art will be aware of the specific implementation structure and will not be described herein.

It should be understood that the detachable connection structure of the ventilator between the device 23, the electrocardiograph monitoring main control module 22, the electrocardiograph monitoring functional module 27 and the defibrillation device 26 and the main body 1 may be a plug-in connection structure in the prior art, that is, the device and the module are connected with the main body 1 in a unit plug-in manner, so that the replacement and maintenance of the device and the module are facilitated, the plug-in connection structure is in the prior art, and the specific structure thereof is not described herein, and a person skilled in the art should know how to implement the function.

Fig. 18 shows embodiment 5 of the present invention.

The same parts of this embodiment as those of embodiment 1 will not be described in detail herein, and in this embodiment, the stand 6 is provided with a lifting device 34, and the height position of the main body 1 can be adjusted by the lifting device 34 so as to adapt to different medical care operation requirements.

It should be noted that in some embodiments, the lifting device 34 may be an electrically adjustable lifting structure, a pneumatically adjustable lifting structure, a hydraulically adjustable lifting structure, or a manually adjustable lifting structure.

It should be understood that the above-mentioned lifting structure of the lifting device 34 is a prior art, and those skilled in the art should know how to implement the specific structure of the function thereof, and will not be described herein.

In some embodiments of the present invention, docking device ii 29 may be provided on a chassis located at the left or right end of transfer bed 28, connecting the emergency equipment of the present invention to the left or right end of transfer bed 28.

In some embodiments of the invention, the chassis 9 may be configured as a frame structure or plate structure, and the configuration of the chassis 9 may be a polygonal structure adapted to a quadrilateral shape, so long as it can move under the underframe of the transfer bed 28 without interfering with the moving wheels of the transfer bed 28.

In some embodiments of the present invention, the push-pull handrail 4 may also be provided on the main body 1, such as the lower end or side of the main body 1.

In some embodiments of the present invention, the oxygen pressure flow monitoring device 2, the UPS power monitoring device 25, the infusion support 13, and the weak current interface may be one or more of them installed on the main body 1 according to actual needs, the infusion support 13 may be fixedly or detachably installed on the main body 1, and the main body 1 may be provided with at least two connection parts of the infusion support 13, so that the installation position of the infusion support 13 may be adjusted according to needs.

In some embodiments of the present invention, the oxygen supply device 17 may also be configured as an oxygen bag/box, in which the oxygen bag/box is not connected to the medical terminal 3, but the oxygen bag directly supplies oxygen through a gas pipe connected to the patient, and in other embodiments, the oxygen supply device 17 may also be configured as an oxygen generator, in which the UPS power supply device 20 is connected to the oxygen generator to supply power thereto, and the oxygen generator is connected to the medical terminal 3 through a pipe.

The specific structures of the oxygen bottle, the oxygen bag/box, the oxygenerator, the corresponding pipe connection and the like in the above embodiment are all the prior art, and those skilled in the art should know how to implement them, so that the description thereof is omitted.

As an adjustment of the installation positions of the oxygen supply device 17, the negative pressure device 21 and the UPS power supply device 20, in some embodiments, the oxygen supply device 17, the negative pressure device 21 and the UPS power supply device 20 may be directly installed on the chassis 9 or the rack 6 through the supporting member and the fixing member, in embodiments where the equipment box 8 is provided, one or more of the above devices may be installed in the equipment box 8, and the rest may be installed on the chassis 9 or the rack 6, in other embodiments, the above devices may be installed in the equipment box 8, and the equipment box 8 may play a role in protecting each device and reducing noise of each device.

It should be noted that the number of the medical terminal 3, the housing portion 16, the power outlet 14, the weak current interface may be increased or decreased according to actual demands.

In an embodiment of the present invention, the weak current interface includes a USB interface, a network port, and the like.

In the embodiment of the invention, the starting power required by each device and module is provided by the UPS power device 20.

Finally, it is noted that although the foregoing embodiments have been described in detail with reference to the embodiments of the present invention, there are alternatives, modifications and equivalents that fall within the scope of the invention. It will be appreciated by those of ordinary skill in the art that there are numerous other ways of implementing the apparatus of the invention, and it is understood that all such alternatives, modifications, and equivalents as may be included within the spirit and scope of the invention.

Claims (14)

1. A mobile critical illness transportation first-aid device, characterized by: including host computer body (1), support (6) and have chassis (9) of removing wheel (10), the host computer body passes through the leg joint the chassis, the host computer body is equipped with medical air terminal (3), strong electric socket (14), weak current interface, storage portion (16), be equipped with oxygen supply unit (17), negative pressure device (21) and UPS power supply unit (20) on support and/or the chassis, the support is equipped with interfacing apparatus I (7), the chassis is movable to the chassis below of transporting bed (28), and through interfacing apparatus I with establish interfacing apparatus II (29) of transporting bed tip are connected fixedly, the host computer body still includes breathing machine subassembly, electrocardio guardianship subassembly, defibrillation subassembly one or more than two and at least one display device (15).

2. A mobile critical illness transportation emergency equipment according to claim 1, characterized in that: the device comprises a main body (1), wherein a bracket (6) and/or a chassis (9) below the main body are/is provided with an equipment box (8), and one or more of an oxygen supply device (17), a negative pressure device (21) and a UPS (uninterrupted power supply) device (20) are/is arranged in the equipment box.

3. A mobile critical illness transportation emergency equipment according to claim 2, characterized in that: the negative pressure device (21) and the UPS power supply device (20) are respectively arranged on the equipment box (8), and the oxygen supply device (17) is fixed on the chassis (9) positioned at the rear side of the bracket (6) through the fixed shield (18).

4. A mobile critical illness transportation emergency equipment according to claim 1 or 2, characterized in that: the support (6) or the main machine body (1) is provided with a push-pull handrail (5).

5. A mobile critical illness transportation emergency equipment according to claim 1, characterized in that: the docking device II (29) is arranged at the end part of the bed tail of the transfer bed (28), and the chassis (9) moves from the end part of the bed tail to the lower part of the underframe of the transfer bed and is connected with the end part of the bed tail of the transfer bed through the docking device I (7) and the docking device II.

6. A mobile critical care equipment according to claim 1 or 5, characterized by: the butt joint device I (7) and the butt joint device II (29) are fixed through a pin shaft (30), and the pin shaft is locked in a matched mode through a fixed block (33), a locking sliding block (31) and a spring (32) which are arranged at one end of the butt joint device I.

7. A mobile critical illness transportation emergency equipment according to any one of claims 1, 2, 5, wherein: the chassis (9) is of a T-shaped structure.

8. A mobile critical care equipment as claimed in claim 1, wherein: the ventilator assembly comprises a ventilator device (23), a breathing function external port (4) and corresponding control keys, wherein the ventilator device is fixedly connected with or can be detached from the main machine body (1), the ventilator device is of an invasive/noninvasive breathing structure, and the ventilator device comprises an air-oxygen mixing module, an air suction module, an air expiration module, a monitoring module, a control module, an air supply driving device, an air inlet, an air outlet and a constant-temperature humidifying device.

9. A mobile critical care equipment as claimed in claim 1, wherein: the electrocardiograph monitoring assembly comprises an electrocardiograph monitoring main control module (22), an electrocardiograph monitoring functional module (27), an electrocardiograph monitoring external port (11) and corresponding control keys, wherein the electrocardiograph monitoring main control module and the electrocardiograph monitoring functional module are integrally or separately constructed in the main machine body (1), the electrocardiograph monitoring main control module and the electrocardiograph monitoring functional module are fixedly connected or detachably connected with the main machine body, and the electrocardiograph monitoring functional module comprises one or more than two of an electrocardiograph module, a heart rhythm module, a heart rate module, a noninvasive/invasive blood pressure module, a breathing module, an oxygen saturation module, a body temperature module and a noninvasive continuous blood pressure module.

10. A mobile critical care equipment as claimed in claim 1, wherein: the defibrillation assembly comprises a defibrillation device (26) and a defibrillation control external connection area (12), and the defibrillation device is fixedly or detachably connected with the main machine body (1).

11. A mobile critical illness transportation emergency equipment according to any one of claims 1, 8, 9, 10, wherein: the infusion support is characterized in that the main body (1) further comprises one or more than two of an oxygen pressure flow monitoring device (2), a UPS electric quantity monitoring device (25) and an infusion support (13), and the infusion support is detachably arranged on the main body.

12. A mobile critical illness transportation emergency equipment according to claim 1, characterized in that: the storage section (16) is configured to store an opening/closing door (24) or a drawer.

13. A mobile critical illness transportation emergency equipment according to claim 1, characterized in that: the support (6) is provided with a lifting device (34), and the lifting device is an electric or pneumatic or hydraulic or manual lifting structure.

14. A mobile critical illness transportation emergency equipment according to any one of claims 1, 2, 3, wherein: the oxygen supply device (17) is of an oxygen bottle structure or an oxygen bag/box structure or an oxygen generator structure.