CN219440432U - Defibrillation monitor - Google Patents

Abstract

A defibrillation monitor comprising: the shell is provided with a monitoring parameter interface and a treatment interface; the first board card, the second board card and the third board card are arranged in the shell; the capacitor mounting position is arranged in the shell; the power supply module installation position comprises a battery installation position and/or a power supply module installation position; and the display screen is arranged on the front side of the shell. The first board card is parallel with the display screen, and second board card and third board card are perpendicular with the display screen, and three board card overall arrangement is compact, especially can reduce the thickness of defibrillation monitor fore-and-aft direction for structural layout in the defibrillation monitor is compacter, is favorable to reducing the volume of defibrillation monitor, and the defibrillation monitor of little volume is more convenient to use under different scenes, and the casing of the defibrillation monitor of little volume is littleer, can alleviate the weight of defibrillation monitor, conveniently carries.

Description

Defibrillation monitor

Technical Field

The utility model relates to the technical field of medical equipment, in particular to a defibrillation monitor.

Background

The defibrillation monitor is a medical instrument for eliminating arrhythmia by using stronger pulse current to pass through the heart, so that the arrhythmia is recovered, and is necessary first-aid equipment for various departments in hospitals. Defibrillation is one of the important steps for performing cardiopulmonary resuscitation.

Typically in emergency systems, the mounting of the defibrillation monitor is divided into a desktop or wall mounting. Under the actual clinical use condition, the existing design of the defibrillation monitor has the condition that the thickness space (the thickness of the equipment in the front-back direction) is large, and has great blocking influence on emergency operation. In emergency systems, the space of the desk top, the wall, the ambulance ship or the helicopter is limited, especially the space of the ambulance ship is limited, and the machine is not expected to occupy too much thickness and size in the desk top installation and the wall installation, so that the utilization of the emergency space is affected. At present, the known monitoring defibrillator in the market has the problems of large size, heavy weight and the like.

Disclosure of Invention

The utility model provides a defibrillation monitor which is used for solving the problem that the defibrillation monitor is large in size and heavy in weight.

In one embodiment, a defibrillation monitor is provided, comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell;

the capacitor mounting position is arranged in the shell;

the power supply module installation position comprises a battery installation position and/or a power supply module installation position; and

The display screen is arranged on the front side of the shell;

the first board card is parallel to the display screen and comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

the second board card and the third board card are perpendicular to the display screen, and the projection parts of the second board card and the third board card are overlapped or completely overlapped on the cross section perpendicular to the display screen along the left-right direction; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.

In one embodiment, the second board card and the third board card are stacked up and down adjacently.

In one embodiment, on a cross section perpendicular to the display screen along the up-down direction, the projection part of at least one component on the lower surface of the second board card and the projection part of at least one component on the upper surface of the third board card are overlapped or completely overlapped.

In one embodiment, the power supply module mounting position includes a battery mounting position, and on a cross section perpendicular to the display screen along a left-right direction, a projection of the battery mounting position is overlapped with or completely overlapped with a projection portion of the second board card, and/or is overlapped with or completely overlapped with a projection portion of the third board card.

In one embodiment, the power module mounting position includes a power module mounting position, and on a cross section perpendicular to the display screen along a left-right direction, a projection of the power module mounting position is overlapped with or completely overlapped with a projection portion of the second board card, and/or is overlapped with or completely overlapped with a projection portion of the third board card.

In one embodiment, in a cross section perpendicular to the display screen along the left-right direction, the projection of the capacitor mounting position is overlapped with or completely overlapped with the projection part of the second board card, and/or is overlapped with or completely overlapped with the projection part of the third board card.

In one embodiment, the second board card and the third board card are located above the power module mounting location and the capacitor mounting location.

In one embodiment, the defibrillation monitor further comprises a recorder mounting location disposed within the housing; and on the cross section vertical to the display screen along the left-right direction, the projection of the installation position of the recorder is overlapped with the projection part of the second board card or is completely overlapped with the projection part of the third board card or is completely overlapped with the projection part of the third board card.

In one embodiment, the power module mounting location and the capacitor mounting location are located above and/or to the side of the recorder mounting location.

In one embodiment, the first board card is closer to the display screen than the second board card and the third board card.

In one embodiment, the battery mounting location is an internal cavity provided in the housing, the internal cavity extending from a rear side to a front side of the housing.

In one embodiment, the power supply module mounting position includes two battery mounting positions, and the battery mounting positions are arranged on the shell; or alternatively

The power supply module installation position comprises a battery installation position and a power supply module installation position, wherein the battery installation position is arranged in the shell, and the power supply module installation position is arranged in the shell.

In one embodiment, the defibrillation monitor has only one of the monitoring parameter modules and/or the defibrillation monitor has only one of the defibrillation therapy modules.

In one embodiment, the control module includes a master control module and a slave control module;

the defibrillation monitor is provided with only one first board card, and the master control module and the slave control module are both positioned on the first board card; or the defibrillation monitor is provided with two first boards which are arranged in parallel, the master control module is positioned on one first board, and the slave control module is positioned on the other first board.

In one embodiment, the second board card further comprises a power management module for connecting with a battery and/or a power module to manage power.

In one embodiment, the defibrillation monitor further comprises a mounting bracket disposed in the housing, the second board card and the third board card are fixed on the mounting bracket, and the mounting bracket comprises a capacitor mounting position and a power module mounting position.

In one embodiment, the mounting frame is detachably connected with the shell.

In one embodiment, the shell comprises a front shell and a rear shell, the front shell and the rear shell are in butt joint, the front shell is of a plate structure, and the rear shell is of a box structure.

In one embodiment, a handle is provided on the upper side of the front housing.

In one embodiment, the handle and the front housing are of unitary construction.

In one embodiment, the defibrillation monitor further comprises a wireless communication unit, at least a portion of the wireless communication unit being disposed on the handle.

In one embodiment, the front shell is provided with an alarm lamp, which is located at the junction of the upper side and the front side of the front shell.

In one embodiment, the monitoring parameter interface and the therapy interface are disposed on the left and right sides of the back shell, respectively.

In one embodiment, the shell comprises a front shell and a rear shell, the front shell and the rear shell are in butt joint, the front shell is of a plate structure, and the rear shell is of a box structure; the first board card is located in the front shell, the second board card, the third board card, the capacitor installation position and the recorder installation position are located in the rear shell, and the battery installation position is arranged on the outer side of the rear shell.

In one embodiment, the top of the shell is provided with two electrode plate grooves, and the electrode plate grooves are used for placing electrode plates.

In one embodiment, the housing is provided with an electrode tab receiving portion.

In one embodiment, a defibrillation monitor is provided comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell; and

the display screen is arranged on the front side of the shell;

the first board card comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

at least one of the second board card and the third board card is arranged along the left-right direction and is perpendicular to the display screen; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.

In one embodiment, a defibrillation monitor is provided comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell; and

the display screen is arranged on the front side of the shell;

the first board card comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

the second board card and the third board card are parallel to the display screen, and the projection parts of the second board card and the third board card are overlapped or completely overlapped on the cross section parallel to the display screen; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.

According to the defibrillation monitor of the embodiment, the first board card is parallel to the display screen, the second board card and the third board card are perpendicular or parallel to the display screen, and the three board cards are compact in layout, so that the thickness of the defibrillation monitor in the front-rear direction can be reduced; on the cross section vertical to the display screen along the left and right directions or on the cross section parallel to the display screen, the projection parts of the second board card and the third board card are overlapped or completely overlapped, so that the structural layout in the defibrillation monitor is more compact, the volume of the defibrillation monitor is reduced, the small-volume defibrillation monitor is more convenient to use in different scenes, the shell of the small-volume defibrillation monitor is smaller, the weight of the defibrillation monitor can be reduced, and the portable defibrillation monitor is convenient to carry.

Drawings

Fig. 1 is a schematic diagram of a defibrillation monitor according to an embodiment;

fig. 2 is a schematic diagram of a defibrillation monitor according to an embodiment;

FIG. 3 is a schematic view of the structure of the front shell in one embodiment;

FIG. 4 is a schematic view of an exploded construction of a front shell portion in one embodiment;

FIG. 5 is a block diagram of the front shell portion of one embodiment;

fig. 6 is a block diagram of a cross section of a defibrillation monitor in an up-down direction in one embodiment;

FIG. 7 is a schematic view of an exploded construction of a rear housing portion in one embodiment;

fig. 8 is a schematic diagram of an exploded view of a defibrillation monitor according to one embodiment;

fig. 9 is a schematic diagram of a defibrillation monitor according to an embodiment;

FIG. 10 is a schematic view of the structure of the front shell in one embodiment;

wherein the reference numerals are as follows:

1-shell, 11-front shell, 12-back shell, 121-monitoring parameter interface, 122-treatment parameter, 123-electrode plate groove, 13-capacitor installation position, 131-capacitor, 14-power supply module installation position, 141-battery installation position, 1411-battery, 142-power supply module installation position, 1421-power supply module, 15-recorder installation position, 151-recorder, 16-installation frame and 17-alarm lamp;

the device comprises a first board card 2, a control module 21, a second board card 3, a monitoring parameter module 31, a power supply management module 32, a third board card 4, a defibrillation treatment module 41, a display screen 5 and function keys 51;

6-handle, 7-electrode plate.

Detailed Description

In an existing defibrillation monitor, each functional module in the defibrillation monitor is respectively installed on each side of a housing, so that each functional module is in butt joint with each interface, for example, a monitoring parameter interface and a treatment interface are respectively arranged on two sides of the housing, and a monitoring parameter module and a defibrillation treatment module in the housing are respectively arranged on two sides of the housing, so that the monitoring parameter module is in butt joint with the monitoring parameter interface, and the defibrillation treatment module is in butt joint with the treatment interface. This arrangement results in a lower utilization of the internal space of the housing and the application of the monitoring parameter module and defibrillation therapy module against the interior sidewall of the housing results in a greater thickness of the defibrillation monitor in the front-to-back direction.

Based on the analysis, the internal layout of the defibrillation monitor is readjusted, and the layout adjustment mainly comprises two aspects: in a first aspect, functional modules in the defibrillation monitor are assembled on at least three boards, each functional module is connected with each interface through a circuit on the board, for example, a monitoring parameter module and a power supply management module are assembled on one board, a main control system and a slave control system are assembled on one board, a defibrillation treatment module is assembled on one board, and the like; in a second aspect, three boards are arranged parallel or perpendicular to the display screen, respectively, wherein the board integrated with the master control system and the slave control system can be arranged close to the display screen and parallel to the display screen, so that the board is abutted against one side of the housing close to the display screen, and two boards integrated with other functional modules are mutually parallel and perpendicular to the display screen, and the projection parts of the second board and the third board are overlapped or completely overlapped on the cross section perpendicular to the display screen or the cross section parallel to the display screen along the left-right direction, so that the defibrillation monitor can take more space, and the space can be used for components (between the boards, a capacitor and the like, and a gap for separation is formed between the boards and other components).

In this application, make casing internals compacter along upper and lower direction range upon range of overall arrangement, reduce unnecessary clearance between each part, more importantly, this along upper and lower direction range upon range of overall arrangement can effectively reduce the occupation space of casing in the fore-and-aft direction, reduces the thickness of defibrillation monitor fore-and-aft direction, and the defibrillation monitor of being convenient for places the use in little space.

The defibrillation monitor has the demand of preventing falling, so the casing of the defibrillation monitor generally adopts the material with high strength or is thicker with the casing wall setting, leads to the weight of the defibrillation monitor great, and this application reduces the inside occupation space of the defibrillation monitor after through the inside rearrangement of the defibrillation monitor, can reduce the casing, reduces the weight of casing, and then can lighten the weight of the defibrillation monitor, makes things convenient for the doctor to carry.

The utility model will be described in further detail below with reference to the drawings by means of specific embodiments. Wherein like elements in different embodiments are numbered alike in association. In the following embodiments, numerous specific details are set forth in order to provide a better understanding of the present application. However, one skilled in the art will readily recognize that some of the features may be omitted, or replaced by other elements, materials, or methods in different situations. In some instances, some operations associated with the present application have not been shown or described in the specification to avoid obscuring the core portions of the present application, and may not be necessary for a person skilled in the art to describe in detail the relevant operations based on the description herein and the general knowledge of one skilled in the art.

Furthermore, the described features, operations, or characteristics of the description may be combined in any suitable manner in various embodiments. Also, various steps or acts in the method descriptions may be interchanged or modified in a manner apparent to those of ordinary skill in the art. Thus, the various orders in the description and drawings are for clarity of description of only certain embodiments, and are not meant to be required orders unless otherwise indicated.

The numbering of the components itself, e.g. "first", "second", etc., is used herein merely to distinguish between the described objects and does not have any sequential or technical meaning. The term "connected" as used herein includes both direct and indirect connection (coupling), where front side refers to the side of the display screen facing the viewer and lower side refers to the side of the defibrillation monitor placed on the table, such that the front-to-back direction is perpendicular to the display screen and the left-to-right direction and the up-and-down direction is parallel to the display screen. In addition, the terms "parallel" and "perpendicular" as used herein are not limited to absolute 180 degrees and 90 degrees, and are intended to be included within the scope of the present utility model as long as they are substantially parallel or substantially perpendicular, for example, within 10 degrees or within 5 degrees, and still achieve the corresponding effects.

In one embodiment, a defibrillation monitor is provided for performing defibrillation as a medical device for emergency equipment. The defibrillation monitor has the advantages of small volume and light weight, and especially has smaller thickness in the front-back direction, and can be used in the limited space scenes such as department desktops, walls, ambulance ships or helicopters, and the like, and is convenient for doctors to carry.

Referring to fig. 1 to 8, the defibrillation monitor of the present embodiment mainly includes a housing 1, a first board 2, a second board 3, a third board 4 and a display 5. The display screen 5 is installed in the front side of casing 1, and display screen 5 is used for showing physiological information such as guardianship parameter and operation interface, and display screen 5 can be conventional screen, sets up the operation button around display screen 5 and operates, and display screen 5 also can be the touch-control screen, can directly operate through display screen 5. The shell 1 is provided with a containing cavity, the first board card 2, the second board card 3 and the third board card 4 are arranged in the containing cavity of the shell 1, the first board card 2, the second board card 3 and the third board card 4 are respectively assembled with functional modules, and the three board cards are used for re-arranging and installing a plurality of functional modules.

The shell 1 comprises a front shell 11 and a rear shell 12, the front shell 11 and the rear shell 12 are in front-back butt joint, the front shell 11 and the rear shell 12 can be fixed in a clamping, screw connection and other modes, and the front shell 11 and the rear shell 12 enclose a containing cavity of the shell 1. The front shell 11 is a plate-card-shaped structure with a certain thickness, the rear shell 12 is a box-type structure, the front side of the rear shell 12 is provided with an opening, the other directions of the rear shell 12 are provided with side walls which are enclosed together, the rear shell 12 can be an integrated structure, and the rear shell 12 can also be formed by enclosing and fixing a plurality of side plates. The front case 11 is mounted on the opening of the front side of the rear case 12, and the front case 11 blocks the opening of the rear case 12.

The front shell 11 is arranged into a board card structure, which is beneficial to improving the structural strength of the whole shell 1. In other embodiments, the front shell 11 and the rear shell 12 may have other structures, for example, the front shell 11 and the rear shell 12 are both box-type structures, and the front shell 11 and the rear shell 12 can also enclose a housing cavity. In other embodiments, the housing 1 may be composed of more than two pieces, i.e., the front case 11 and/or the rear case 12 may be further formed by combining a plurality of pieces, for example, the rear case 12 includes a bottom plate, a top plate, and a side plate, and the bottom plate, the top plate, and the side plate enclose the rear case 12 having an opening on a front side. In other embodiments, the housing 1 may not be limited to the front-rear split form, but may be an upper-lower split, a left-right split, or other combinations. In other embodiments, the housing 1 may be an integrated structure, for example, an opening is provided at the front side of the housing 1, the components in the housing 1 are mounted in the housing 1 through the opening, the display 5 is mounted on the front shell of the housing 1, and the display 5 seals the opening at the front side of the housing 1.

In one embodiment, the front shell 11 is made of a hard material, such as an alloy, to increase the structural strength of the front shell 11. The front side of preceding shell 11 is equipped with indent structure, and display screen 5 installs in the indent structure of preceding shell 11 for display screen 5 is installed in the front side of preceding shell 11 through the mode of inlaying, and the front side of display screen 5 and the front side parallel and level of preceding shell 11 or relative indent. The front concave structure of the front case 11 may be integrally formed by the structure of the front case 11 itself; the concave structure can also be formed by enclosing an outer protective layer arranged on the front shell 11, a hollowed-out area is arranged in the middle of the outer protective layer, and the inner concave structure is formed by the outer protective layer and the front side surface of the front shell 11.

The front side of the front case 11 may be provided with a plurality of function keys 51 having different functions, such as a power on/off key, a start key, a stop key, and the like. The plurality of function keys 51 are arranged on the same side of the display screen 5, so that the operation of a doctor is facilitated, and if the plurality of function keys 51 are all arranged on the right side of the display screen 5, the right-hand operation of the doctor is facilitated.

In one embodiment, the front case 11 is provided in a tilt structure, with the bottom surface of the front case 11 as a reference, the portion above the bottom surface of the front case 11 is tilted with respect to the bottom surface, particularly, is tilted rearward, i.e., the upper end of the front case 11 is further rearward with respect to the lower end in the front-rear direction. The front shell 11 is arranged in an inclined mode, so that the display screen 5 is in an inclined state, a doctor can conveniently watch the display screen 5, and meanwhile, the doctor can conveniently operate the function keys 51.

In other embodiments, the front case 11 may be disposed vertically, and the display screen 5 on the front side of the front case 11 is in a vertical state.

In one embodiment, the back shell 12 is provided with a monitoring parameter interface 121 and a treatment interface 122, and the monitoring parameter interface 121 and the treatment interface 122 are respectively arranged at the left side and the right side of the back shell 12. The monitoring parameter interface 121 includes multiple interface terminals for connecting different external devices, such as the monitoring parameter interface 121 can be connected with various monitoring sensors via cables, and the monitoring parameter interface 121 can include ECG, spO2, NIBP, IBP, TEMP and CO ₂ One or more of the interfaces for receiving corresponding monitored parameter data. The treatment interface 122 is mainly used for externally connecting electrode plates or electrode plates, and the monitoring parameter interface 121 and the treatment interface 122 are respectively arranged on two sides of the rear shell 12, so that mutual interference of cables can be avoided, and more monitoring parameter interfaces 121 can be arranged on the same side of the rear shell 12.

In other embodiments, the monitoring parameter interface 121 and the therapy interface 122 may be disposed on the left side or the right side of the rear housing 12 at the same time, and the monitoring parameter interface 121 and the therapy interface 122 are distributed at the upper end and the lower end of the same side of the rear housing 12, so as to avoid mutual interference of cables.

In other embodiments, the monitoring parameter interface 121 and the therapy interface 122 may be disposed on the front housing 11 when the front housing 11 is also a box-type structure.

In one embodiment, the first board 2 is a system board, the first board 2 includes a control module 21, the control module 21 includes a master control module and a slave control module, the master control module and the slave control module are integrated on the first board 2, the slave control module is used for separately controlling functions such as defibrillation, and the master control module is used for controlling other functions beyond the control of the slave control module. The division of the control module 21 into a master control module and a slave control module facilitates the rational distribution of process control capabilities, reducing power consumption and improving control efficiency.

In other embodiments, only one control module may be disposed on the first board 2, and one control module may also be capable of controlling all functions of the defibrillation monitor.

In other embodiments, the first board 2 may also include two parallel first boards, where the two first boards are parallel to the display screen 5, and the master control module is integrated on one first board, and the slave control module is integrated on the other first board, so that the master control module and the slave control module are respectively installed, which is beneficial to respectively maintaining the master control module and the slave control module.

In an embodiment, the rear side of the front shell 11 also has a concave structure, the concave structure is located in the accommodating cavity of the housing 1, the first board card 2 is installed in the concave structure of the rear side of the front shell 11, the first board card 2 is arranged in parallel with the display screen 5, and the display screen 5, the front shell 11 and the first board card 2 form a sandwich structure along the front-rear direction, so that the structure is compact. The front shell 11 is provided with a threading hole, the display screen 5 and the function keys 51 are respectively connected with the first board card 2 through cables or flat cables in a signal mode, and the cables or flat cables penetrate through the threading hole in the front shell 11. The control module 21 on the first board 2 is used for controlling the display content of the display screen 5, and the display screen 5 and the function keys 51 are used for inputting control instructions to the control module 21. In other embodiments, some or all of the first board 2 may not be parallel to the display 5, for example, may be perpendicular to the display 5.

In an embodiment, the second board card 3 and the third board card 4 are located at the rear side of the first board card 2, the second board card 3 and the third board card 4 are located at the upper end position in the rear shell 12, the second board card 3 and the third board card 4 are stacked up and down, a space for installing other components is provided below the second board card 3 and the third board card 4, the second board card 3 is located above the third board card 4, and the third board card 4 can also be located above the second board card 3. The second board card 3 and the third board card 4 are arranged in parallel with each other, and the second board card 3 and the third board card 4 are perpendicular to the display screen 5, i.e. the second board card 3 and the third board card 4 are perpendicular to the first board card 2. The projections of the second board card 3 and the third board card 4 are completely overlapped or mostly overlapped on the cross section perpendicular to the display screen 5 along the left-right direction, namely, the second board card 3 and the third board card 4 are in the up-down direction. The second board card 3 and the third board card 4 are provided with a certain interval, the interval space is used for installing components, the components on the lower surface of the second board card 3 and the components on the upper surface of the third board card 4 can be arranged in a staggered manner according to the respective heights, and the projection parts of at least one component on the lower surface of the second board card 3 and at least one component on the upper surface of the third board card are overlapped or completely overlapped on the cross section vertical to the display screen along the up-down direction, so that the installation of the components can be met due to the smaller interval between the second board card 3 and the third board card 4, and the occupation space of the second board card 3 and the third board card 4 is reduced. In other embodiments, the first board card may be disposed parallel to the second board card and the third board card, so as to further compress the dimension in the front-rear direction. In other embodiments, one of the second board 3 and the third board 4 may be parallel to the display 5, and the other may be perpendicular to the display 5, so that the dimension in the up-down direction may be compressed. In other embodiments, the second board card 3 and the third board card 4 may be parallel to the display screen 5, and on a cross section parallel to the display screen, that is, the projections of the second board card 3 and the third board card 4 in the front-rear direction are completely overlapped or mostly overlapped; on a cross section parallel to the display screen, the projection part of at least one component on the rear surface of the second board card 3 and at least one component on the front surface of the third board card 4 are overlapped or completely overlapped.

In other embodiments, the second board card 3 and the third board card 4 may be staggered in the left-right direction or the front-rear direction, where the projection portions of the second board card 3 and the third board card 4 in the up-down direction or the front-rear direction overlap, and the second board card 3 and the third board card 4 are staggered with each other, which is also beneficial for the staggered arrangement of the components on the second board card 3 and the third board card 4, so that a smaller space can be set between the second board card 3 and the third board card 4, and the occupied space is reduced. In one embodiment, the second board card 3 is a parameter board card, the second board card 3 includes a monitoring parameter module 31, the monitoring parameter module 31 is connected to the monitoring parameter interface 121 through a circuit on the second board card 3, an external device is connected to the monitoring parameter module 31 through the monitoring parameter interface 121, and the monitoring parameter module 31 is used for processing monitoring parameter data. In some embodiments, the defibrillation monitor has only one monitoring parameter module 31, which is disposed on the second board 3, and the monitoring parameter module in the defibrillation monitor is integrated on one board, so that the functional modules can be effectively integrated and concentrated, and meanwhile, the occupation of the internal space is saved. In other embodiments, the defibrillation monitor may also include a fourth board card and a plurality of monitoring parameter modules 31, wherein a portion of the monitoring parameter modules 31 are disposed on the second board card 3, a portion of the monitoring parameter modules 31 are disposed on the fourth board card, and the fourth board card may be disposed parallel or perpendicular to the second board card. The distribution of the monitoring parameter modules 31 over multiple boards helps to reduce the area of the second board 3 and gives the components a greater degree of flexibility.

In one embodiment, the second board 3 further includes a power management module 32, where the monitoring parameter module 31 and the power management module 32 are integrated on the first board 3, and the power management module 32 is configured to connect with a battery and/or a power module to manage power supply.

In one embodiment, the third board 4 is a treatment board, the third board 4 includes a defibrillation treatment module 41, the defibrillation treatment module 41 is connected to the treatment interface 122 through a circuit on the third board 4, the defibrillation treatment module 41 is connected to an electrode pad or an electrode plate through the treatment interface 122, and the defibrillation treatment module 41 is used to implement defibrillation treatment functions, such as controlling charging and discharging of the capacitor 1311. In some embodiments, there is only one defibrillation treatment module 41 in the defibrillation monitor, which is disposed on the third board 4, and the defibrillation treatment module in the defibrillation monitor is integrated on one board, so that the functional modules can be effectively integrated and concentrated, and meanwhile, the internal space occupation is saved. In other embodiments, the defibrillation monitor may also include a fifth board card and a plurality of defibrillation treatment modules 41, wherein a portion of the defibrillation treatment modules 41 are disposed on the third board card 4, a portion of the defibrillation treatment modules 41 are disposed on the fifth board card, and the fifth board card may be disposed parallel or perpendicular to the third board card 4. The distribution of defibrillation therapy module 41 across multiple boards helps to reduce the area of third board 4 and gives the components greater flexibility.

In other embodiments, the power management module 32 may be provided on a single board. If three boards parallel to each other are provided, the monitoring parameter module 31, the power management module 32 and the defibrillation treatment module 41 are respectively provided on the three boards. Alternatively, the power management module 32 may be provided on a board card adjacent to the power module and/or the battery.

In one embodiment, the first board 2 is connected to the second board 3 and the third board 4, respectively, and the control module on the first board 2 is used to control the functional modules on the second board 3 and the third board 4 to operate.

In other embodiments, the functions and the included components of the second board 3 and the third board 4 may be interchanged, without affecting the implementation of the solution of the present utility model.

In one embodiment, the defibrillation monitor further includes a capacitor mounting location 13, a power supply module mounting location 14, and a recorder mounting location 15, where the capacitor mounting location 13 and the recorder mounting location 15 are located in the accommodating cavity of the housing 1, and the capacitor mounting location 13 and the recorder mounting location 15 are located in the space below the second board 3 and the third board 4. Wherein, the capacitor mounting position 13 is used for mounting the capacitor 1311, and the recorder mounting position 15 is used for mounting the recorder 151. The capacitor mounting position 13 and the recorder mounting position 15 may be formed by integrally projecting structures on the inner side of the rear case 12, or may be provided on a mounting member in the rear case 12.

In one embodiment, the power supply module mounting location 14 may be an inner cavity formed by extending from the rear side to the front side of the housing 1, and located on two opposite sides of the housing from the accommodating cavity, where the inner cavity may be used as a battery mounting location 141 for mounting the battery 1411, and may be provided with a avoidance hole or opening for routing; and/or, the housing cavity of the housing 1 may also be provided with a power module mounting location 14, for example, a power module mounting location 142 may be provided for mounting the power module 1421. The battery 1411 is an energy storage battery, and the defibrillation monitor can work under the condition of no power plug after the battery 1411 is installed; the power module 1421 is mainly used for converting voltage, and converting externally connected mains voltage into voltage used by the defibrillation monitor. The battery 1411 and the power module 1421 are both connected to the power management module 32, and the power management module 32 is configured to manage power supply of the battery 1411 and the power module 1421.

In one embodiment, in the up-down direction, the projections of the capacitor mounting position 13, the power supply module mounting position 14 and the recorder mounting position 15 are partially or completely overlapped with the projections of the second board card 3 and the third board card 4, for example, the projections of the power supply module mounting position 14 and the recorder mounting position 15 are positioned near the middle of the accommodating cavity, and the projections of the power supply module mounting position 14 and the recorder mounting position 15 are completely overlapped with the projections of the second board card 3 and the third board card 4; alternatively, the recorder mounting position 15 is located at one side of the accommodating cavity, and the projection of the recorder mounting position 15 coincides with the projection portions of the second board card 3 and the third board card 4.

In one embodiment, the capacitor mounting position 13 is located at one side of the therapeutic interface 122, the power supply module mounting position 14 is located at a middle position, a space of the recorder mounting position 15 is further provided below the power supply module mounting position 14, and the recorder mounting position 15 may be located below the capacitor mounting position 15 or at a side opposite to the therapeutic interface, so that the capacitor 1311 mounted by the capacitor mounting position 13 is close to the therapeutic interface 122, which is beneficial to shortening the connection distance between the capacitor 1311 and the therapeutic interface 122; the battery 1411 and/or the power module 1421 mounted on the power module mounting location 14 is proximate to the second board 3 and the monitoring parameter interface 121, which also facilitates connection of the battery 1411 and/or the power module 1421 to the second board 3. The recorder installation position 15 is positioned at the lowest part, a lower opening is arranged below the rear shell 12 and is connected with the recorder installation position 15 up and down, so that the recorder 151 installed on the recorder installation position 15 can replace printing paper through the opening; the lower end of the front case 11 may also be provided with a front opening for ejecting data or pictures printed by the recorder 151, which is connected to the recorder mounting position 15 back and forth.

In other embodiments, the capacitor mounting location 13, the power module mounting location 14 and the recorder mounting location 15 may be arranged in other arrangements, such as when the power module mounting location 14 includes a battery mounting location 141 or a power module mounting location 142, the capacitor mounting location 13 and the power module mounting location 14 may be arranged side by side, and the recorder mounting location 15 may be located below both the capacitor mounting location 13 and the power module mounting location 14, which may also enable a compact arrangement.

In other embodiments, the recorder mounting position 15 may not be provided in the defibrillation monitor, and the defibrillation monitor may also print and record data of the defibrillation monitor through the monitoring parameter interface 121 and an external recorder.

In one embodiment, the defibrillation monitor includes a capacitor mounting location 13, a power module mounting location 14, and a recorder mounting location 15, the defibrillation monitor does not include a capacitor 1311, a battery 1411, a power module 1421, and a recorder 151, and the capacitor 131, the battery 1411, the power module 1421, and the recorder 151 are installed into the defibrillation monitor after the defibrillation monitor leaves the factory.

In other embodiments, the defibrillation monitor includes a capacitor 131, a battery 1411, a power module 1421, and a recorder 151, and the capacitor 131, the battery 1411, the power module 1421, and the recorder 151 are shipped with the defibrillation monitor and pre-installed on corresponding installation sites.

In one embodiment, the top of the housing 1 is further provided with two electrode plate grooves 123, the two electrode plate grooves 123 are arranged side by side on the top surface of the rear housing 12, and the two electrode plate grooves 123 are used for fixing one electrode plate 7 respectively. The electrode plate groove 123 can be internally provided with a clamping part, the clamping part can be a convex elastic terminal or a spring plate and other structures, and the clamping part is used for fixing the electrode plate 7 in the electrode plate groove 123 and preventing the electrode plate from falling down in the carrying process.

In other embodiments, the top of the housing 1 may not be provided with the electrode plate groove 123, and the defibrillation monitor is provided with an electrode plate accommodating portion, for example, the electrode plate accommodating portion is provided with an accommodating bag for accommodating the left and right sides of the defibrillation monitor, and the defibrillation monitor performs defibrillation by connecting the electrode plate, and the electrode plate is accommodated in the accommodating bag when not in use.

In one embodiment, a mounting bracket is also provided within the housing 1 of the defibrillation monitor.

Referring to fig. 8, in the present embodiment, a mounting rack 16 is installed in the accommodating cavity of the housing 1, and the mounting rack 16 is detachably installed in the rear housing 12. The second and third boards 3 and 4 are fixed to the mounting frame 16, and the capacitor mounting position 13 and the power module mounting position 142 are provided on the mounting frame 16 so that the capacitor 1311 and the power module 1421 are fixed to the mounting frame 16. The mounting frame 16 is also provided with a hollowed-out area for avoiding the battery 1411 and the recorder 151.

The second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 are fixed on the mounting rack 16, so that the second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 are convenient to install and maintain. During installation, the second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 are firstly installed on the installation frame 16 respectively, and then the installation frame 16 provided with the second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 is installed in the rear shell 12; in the process of disassembly, the mounting frame 16 with the second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 is taken out from the rear shell 12, and then the second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 are disassembled. The second board card 3, the third board card 4, the capacitor 1311 and the power module 1421 can be operated outside the rear shell 12 in the process of installation or maintenance and disassembly, and compared with the operation in the narrow rear shell 12, the assembly and disassembly are more convenient and the disassembly effect is higher.

In this embodiment, the mounting frame 16 may be an integrated structure to improve the structural strength of the mounting frame 16. In other embodiments, the mounting bracket 16 may be assembled from a plurality of structures.

In this embodiment, the installation of the installation frame 16 in the housing 1 can facilitate the installation of each component in the housing 1, and can also improve the stability of each component in the housing 1.

In one embodiment, the defibrillation monitor is further provided with an integrally constructed handle.

Referring to fig. 9 and 10, in the present embodiment, the upper end of the front housing 11 may be integrally formed with the handle 6, and since the structural strength of the front housing 11 is greater than that of the rear housing 12, the center of gravity of the defibrillator is biased to the front side, and the handle 6 is disposed at the front side to enable the defibrillator to be lifted and carried more stably. Anti-slip structures such as anti-slip lines can be arranged on the handle 6 to improve the holding stability and prevent the defibrillation monitor from being broken in the carrying process.

In other embodiments, the handle 6 may also be mounted on the rear housing 12, near the front housing 11; or the handle 6 is arranged at the joint between the front shell 11 and the rear shell 12, and the handle 6 is connected with the front shell 11 and the rear shell 12 at the same time, so that a doctor can conveniently carry the defibrillation monitor. In other embodiments, the handle and the front and/or rear shells may be of a split construction.

In one embodiment, the defibrillation monitor further includes a wireless communication unit, the wireless communication unit is installed in the handle 6, the handle 6 is partially set to be in a nonmetal structure, or a communication antenna connected with the wireless communication unit is arranged at the edge of the handle 6, so that the wireless communication outside the wireless communication unit can be realized. The wireless communication unit is connected with the first board card 2 in the housing 1 through a signal line.

In other embodiments, the wireless communication unit may be disposed at an upper end of the front case 11 or the rear case 12, and may also implement a wireless communication function.

In an embodiment, the upper end of the front shell 11 is further provided with an alarm lamp 17, the alarm lamp 17 can be arranged at the edge position of the middle part of the top of the front shell 11, the top surface of the alarm lamp 17 is exposed out of the top surface of the front shell 11, the front side surface of the alarm lamp 17 is exposed out of the front side surface of the front shell 11, namely, two surfaces of the alarm lamp 17 are respectively exposed out of the front surface and the top surface of the defibrillation monitor, and a doctor can observe alarm information displayed by the alarm lamp 17 more easily.

In other embodiments, a plurality of alarm lamps 17 may be provided, and the plurality of alarm lamps 17 may be provided on different sides of the housing 1, so that if they are provided on the front side and the top surface, the doctor can easily observe the alarm information displayed by the alarm lamps 17.

In this embodiment, the alarm lamp 17 is connected with the first board card 2 in the housing 1 through a signal line, and the alarm lamp 17 displays different alarm information by different colors and different brightness colors.

In other embodiments, an alarm horn may be further disposed on the defibrillation monitor, and the alarm horn and the alarm lamp 17 cooperate to realize an audible and visual alarm.

The foregoing description of the utility model has been presented for purposes of illustration and description, and is not intended to be limiting. Several simple deductions, modifications or substitutions may also be made by a person skilled in the art to which the utility model pertains, based on the idea of the utility model.

Claims (28)

1. A defibrillation monitor, comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell;

the capacitor mounting position is arranged in the shell;

the power supply module installation position comprises a battery installation position and/or a power supply module installation position; and

the display screen is arranged on the front side of the shell;

the first board card is parallel to the display screen and comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

The second board card and the third board card are perpendicular to the display screen, and the projection parts of the second board card and the third board card are overlapped or completely overlapped on the cross section perpendicular to the display screen along the left-right direction; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.

2. The defibrillation monitor of claim 1, wherein the second board card and the third board card are stacked adjacent one another.

3. The defibrillation monitor of claim 2, wherein the projection of at least one component of the lower surface of the second board and at least one component of the upper surface of the third board partially overlap or completely overlap in a cross section perpendicular to the display screen in the up-down direction.

4. The defibrillation monitor of claim 1, wherein the power module mounting location comprises a battery mounting location having a projection that partially or fully coincides with a projection of the second board and/or partially or fully coincides with a projection of the third board in a cross-section perpendicular to the display screen in a left-right direction.

5. The defibrillation monitor of claim 1, wherein the power module mounting location comprises a power module mounting location having a projection that partially or fully coincides with a projection of the second board and/or partially or fully coincides with a projection of the third board in a cross section perpendicular to the display screen in a left-right direction.

6. The defibrillation monitor of claim 1, wherein the projection of the capacitor mounting location partially or fully coincides with the projection of the second board and/or partially or fully coincides with the projection of the third board in a cross section perpendicular to the display screen in the left-right direction.

7. The defibrillation monitor of claim 1, wherein the second board card and the third board card are positioned above the power module mounting location and the capacitance mounting location.

8. The defibrillation monitor of claim 1, further comprising a recorder mount located within the housing; and on the cross section vertical to the display screen along the left-right direction, the projection of the installation position of the recorder is overlapped with the projection part of the second board card or is completely overlapped with the projection part of the third board card or is completely overlapped with the projection part of the third board card.

9. The defibrillation monitor of claim 8, wherein the power module mounting location and the capacitance mounting location are located above and/or to the side of the recorder mounting location.

10. The defibrillation monitor of claim 1, wherein the first board card is closer to the display screen than the second and third board cards.

11. The defibrillation monitor of claim 1, wherein the battery mounting location is a recessed cavity provided in the housing, the recessed cavity extending from a rear side to a front side of the housing.

12. The defibrillation monitor of claim 1, wherein the power module mounting locations include two of the battery mounting locations, the battery mounting locations being disposed on the housing; or alternatively

The power supply module installation position comprises a battery installation position and a power supply module installation position, wherein the battery installation position is arranged in the shell, and the power supply module installation position is arranged in the shell.

13. The defibrillation monitor of claim 1, wherein the control module includes a master control module and a slave control module;

the defibrillation monitor is provided with only one first board card, and the master control module and the slave control module are both positioned on the first board card; or the defibrillation monitor is provided with two first boards which are arranged in parallel, the master control module is positioned on one first board, and the slave control module is positioned on the other first board.

14. The defibrillation monitor of claim 1, wherein the second board further comprises a power management module for interfacing with a battery and/or a power module to manage power.

15. The defibrillation monitor of claim 1, further comprising a mounting bracket disposed within the housing, the second and third board cards being secured to the mounting bracket, and the mounting bracket including the capacitor mounting location and the power module mounting location.

16. The defibrillation monitor of claim 15, wherein the mount is detachably connected to the housing.

17. The defibrillation monitor of any one of claims 1-16, wherein the housing includes a front housing and a rear housing, the front housing and the rear housing being butt-jointed, the front housing being of a plate-type construction and the rear housing being of a box-type construction.

18. The defibrillation monitor of claim 17, wherein the upper side of the front housing is provided with a handle.

19. The defibrillation monitor of claim 18, wherein the handle and the front housing are of unitary construction.

20. The defibrillation monitor of claim 18, further comprising a wireless communication unit, at least a portion of the wireless communication unit being disposed on the handle.

21. The defibrillation monitor of claim 17, wherein the front housing is provided with an alarm light located at a junction of an upper side and a front side of the front housing.

22. The defibrillation monitor of claim 17, wherein the monitoring parameter interface and the therapy interface are disposed on left and right sides of the rear housing, respectively.

23. The defibrillation monitor of claim 8, wherein the housing includes a front shell and a rear shell, the front shell and the rear shell being in butt-joint connection, the front shell being of a plate structure, the rear shell being of a box type structure; the first board card is located in the front shell, the second board card, the third board card, the capacitor installation position and the recorder installation position are located in the rear shell, and the battery installation position is arranged on the outer side of the rear shell.

24. The defibrillation monitor of claim 1, wherein the top of the housing is provided with two electrode plate slots for receiving electrode plates.

25. The defibrillation monitor of claim 1, wherein the housing is provided with an electrode pad receiving portion.

26. The defibrillation monitor of claim 1, wherein the defibrillation monitor has only one of the monitoring parameter modules and/or the defibrillation monitor has only one of the defibrillation therapy modules.

27. A defibrillation monitor, comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell; and

the display screen is arranged on the front side of the shell;

the first board card comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

at least one of the second board card and the third board card is arranged along the left-right direction and is perpendicular to the display screen; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.

28. A defibrillation monitor, comprising:

the device comprises a shell, a monitoring device and a control device, wherein the shell is provided with a monitoring parameter interface and a treatment interface;

the first board card, the second board card and the third board card are arranged in the shell; and

the display screen is arranged on the front side of the shell;

the first board card comprises a control module, and the control module is respectively connected with the display screen, the second board card and the third board card to control the operation of the defibrillation monitor;

the second board card and the third board card are parallel to the display screen, and the projection parts of the second board card and the third board card are overlapped or completely overlapped on the cross section parallel to the display screen; the second board card comprises a monitoring parameter module which is connected with the monitoring parameter interface and is used for processing monitoring parameter data; the third board card comprises a defibrillation treatment module which is connected with the treatment interface and is used for implementing defibrillation treatment functions.