CN112890788A - Real-time dynamic ward monitoring device based on big data acquisition - Google Patents

Abstract

The invention discloses a real-time dynamic ward monitoring device based on big data acquisition, which comprises a machine box, an installation clamping groove, a display, a limiting groove, a limiting component, an adjusting component, a monitoring detection probe, a fixer and a bandage, wherein the bottom of the machine box is sealed on a chassis through a fixing screw, the lower end of the chassis is provided with the monitoring detection probe, the upper end of the chassis is provided with an MCU module, a data receiving module, a contrastive analysis module, an alarm module, a storage module and a wireless connection module by utilizing a circuit board, the monitoring detection probe monitors physiological characteristic data of a patient and transmits the physiological characteristic data to the MCU module through the data receiving module, the MCU module calls all stored case information of the patient in the storage module to be contrasted, calculated and analyzed by utilizing the contrastive analysis module and put on a display screen, once the body of the patient is abnormal, the MCU module controls the wireless connection module, the doctor can quickly diagnose and judge the state of the patient by looking up the comparison data on the display.

Description

Real-time dynamic ward monitoring device based on big data acquisition

Technical Field

The invention relates to the technical field of big data application, in particular to real-time dynamic monitoring equipment based on a big data acquisition ward.

Background

A monitor is a device or system that measures and controls physiological parameters of a patient, compares them to known settings, and sends an alarm if an excessive level is present. The monitor is suitable for medical and health care institutions, is used for monitoring a plurality of physiological characteristic parameters of electrocardio, respiration, body temperature, pulse oxygen saturation, pulse rate, noninvasive blood pressure and the like of adults, children and newborns, displays, reviews, stores and outputs monitored information, and can give an alarm for abnormal monitoring signals.

However, the currently used monitor can only perform simple data analysis, real-time data cannot be compared with previous data, and an effective data support basis for accurately judging the state of an illness of a patient cannot be directly provided for a doctor, so that the diagnosis efficiency of the state of the illness of the patient is influenced; moreover, most of the existing monitors are wired, and various detection instrument circuits are fixed on the body of a patient, so that the patient is not only uncomfortable, but also is easy to loosen and fall off when the patient turns over, and the real-time monitoring of the patient is influenced.

Therefore, a real-time dynamic monitoring device based on a big data acquisition ward is provided.

Disclosure of Invention

The present invention aims to provide a real-time dynamic monitoring device for a large data collection-based ward, thereby solving the problems set forth in the background above.

In order to achieve the purpose, the invention provides the following technical scheme: a real-time dynamic monitoring device based on a big data acquisition ward comprises a machine box, an installation clamping groove, a display, a limiting groove, a limiting component, an adjusting component, a monitoring detection probe, a fixer and a bandage, wherein the installation clamping groove is formed in the middle of the upper end of the machine box, one end of the installation clamping groove extends to the outer wall of one side of a back plate of the machine box, the display is movably clamped and fixed in the installation clamping groove, the limiting groove is respectively and symmetrically formed in the edges of two sides of a top port of the installation clamping groove, the limiting component is respectively arranged between the inner walls of the limiting groove and is movably connected with the adjusting component arranged at two ends of the front side wall of the machine box, the monitoring detection probe is fixedly connected to the bottom of the machine box, the fixer is arranged in the middle of the side wall of the machine box on one side of the monitoring detection probe, the bandage is fixedly connected to the middle of the outer wall of the other side of the, and the outer wall of one side of the binding band close to the case is also provided with an integrated flat air bag.

Furthermore, function buttons are uniformly arranged on the edge of the top of the machine box outside the limiting groove, heat dissipation grids are symmetrically arranged on the outer walls of the two sides of the machine box respectively, and a dust screen is arranged between the inner walls of the heat dissipation grids; corresponding chutes are respectively formed in the inner walls of two sides of the mounting clamping groove at the lower end of the limiting groove, connecting rods are respectively and fixedly connected to the outer walls of two sides of the display corresponding to the chutes, steel balls are respectively movably sleeved at the tail ends of the connecting rods far away from the side walls of the display, and the steel balls are respectively movably clamped in the inner cavities of the chutes.

Furthermore, the machine box is of a lower end opening structure, the bottom of the machine box is sealed with a chassis through a fixing screw, a circuit board is arranged at the upper end of the chassis, an MCU module, a data receiving module, a contrastive analysis module, an alarm module, a power supply module and a storage module are sequentially arranged at the upper end of the circuit board, and the MCU module, the data receiving module, the contrastive analysis module, the alarm module, the power supply module and the storage module are electrically connected with one another.

Furthermore, the data receiving module is electrically connected with the monitoring detection probe through a wire, when the case is bound on the arm of the patient, the lower end of the monitoring detection probe is contacted with the arm of the patient to carry out physiological characteristics of the patient, and the monitoring detection probe detects physiological characteristic data including electrocardio, respiration, body temperature, pulse oxygen saturation, pulse rate and non-invasive blood pressure.

Furthermore, the circuit board is also provided with a wireless connection module, the wireless connection module is electrically connected with the MCU module, and the MCU module is connected with a host computer of the nurse station through the wireless connection module.

Further, spacing subassembly includes the pivot, the connecting rod, clamp plate and gear one, symmetry fixedly connected with connecting rod respectively on the both ends lateral wall of pivot, the pivot passes through the connecting rod to set up between the lateral wall of spacing groove, and be provided with integrative clamp plate on one side outer wall of pivot, the bottom of clamp plate and the flat display top end parallel and level of arranging in the mounting groove in, the end of the connecting rod of pivot one end extends to inside the machine box, fixedly connected with integrative gear one on its terminal outer wall, only set up half a circle of tooth on the outer wall of gear one, and gear one links to each other with the regulating assembly activity.

Further, the adjusting component comprises an adjusting knob, a rotating rod and a second gear, the adjusting knob is attached to the side wall of the machine box, the rotating rod is fixedly connected to the outer wall of one end of the adjusting knob, one end, far away from the adjusting knob, of the rotating rod penetrates through the side wall of the machine box and extends to the inside of the machine box, the second gear is fixedly sleeved at the tail end of the rotating rod inside the machine box, and the second gear is meshed with the first gear.

Further, the fixer includes the fixed plate, U type frame, the movable rod, spacing fixture block, the retaining member, chucking tooth and snap ring, fixed plate fixed connection is in the positive lateral wall middle part department of quick-witted box, and be provided with U type frame on the lateral wall of fixed plate one end, be provided with the movable rod between the terminal side wall about U type frame, be provided with spacing fixture block on the fixed plate outer wall of movable rod expansion end, spacing fixture block is provided with the retaining member on keeping away from the outer wall of fixed plate one side, retaining member hasp movable rod expansion end, the chucking tooth evenly sets up on the outer wall that the movable rod is close to movable rod one side, be provided with the snap ring on the outer wall of one side.

Further, the retaining member includes the fixed lantern ring, the sleeve, the axostylus axostyle, coupling spring and U type card strip, and fixed lantern ring difference fixed connection is lower extreme border department on the outer wall of fixed plate one side is kept away from to spacing fixture block, and the sleeve cup joints in the inner chamber of the fixed lantern ring through the axostylus axostyle activity of afterbody respectively, and is provided with coupling spring on the inner wall that the sleeve corresponds the port, and two arms of U type card strip are movable respectively and cup joint in telescopic inner chamber, and U type card strip support arm end links to each other with coupling spring.

Compared with the prior art, the invention has the following beneficial effects:

1. the invention provides a real-time dynamic monitoring device based on a large data acquisition ward, a movable rod is arranged at the middle part of the side wall of the front face of a case by utilizing a fixed plate to be matched with a U-shaped frame, a limiting fixture block is arranged on the outer wall of the fixed plate at the movable end of the movable rod to clamp the movable end of the movable rod, clamping teeth and clamping rings are respectively arranged on the outer walls of two sides of the movable rod, a locking member is arranged on the outer wall of one side of the limiting fixture block, which is far away from the fixed plate, a U-shaped clamping strip is arranged by utilizing a fixed lantern ring, a sleeve, a shaft lever and a connecting spring, a binding belt arranged at the middle part of the outer wall of the other side of the case corresponding to a fixer is clamped by the clamping teeth on the outer wall of the movable rod, the movable end of the movable rod is clamped in a notch of the limiting fixture block, the U-shaped clamping strip is pulled to stretch, the monitoring device is worn on the arm quickly to perform wireless monitoring, and the problem that the traditional monitor line is used for obstructing use is avoided.

2. The invention provides real-time dynamic monitoring equipment based on a big data acquisition ward, wherein a chassis is sealed at the bottom of a machine box through a fixing screw, a monitoring detection probe is arranged at the lower end of the chassis, and utilize the circuit board to set up the MCU module in chassis upper end, data receiving module, contrastive analysis module, alarm module, storage module and wireless connection module, the monitoring test probe monitoring patient physiological characteristic data transmits the MCU module for through data receiving module, the MCU module calls all storage case information of patient in the storage module and utilizes contrastive analysis module to carry out contrastive calculation analysis and put in on the display screen, in case patient's health appears unusually, MCU module control wireless connection module connects nurse station host computer and reports to the police and calls medical personnel, the doctor looks over the contrast data on the display and can diagnose and treat the judgement to patient's state of an illness fast, utilize big data contrast to realize the real-time guardianship to patient.

3. The invention provides real-time dynamic monitoring equipment based on a big data acquisition ward, which is characterized in that an installation clamping groove and a limiting groove are arranged at the top of a machine box, a display is movably clamped in an inner cavity of the installation clamping groove through a sliding groove on the side wall of the installation clamping groove, a rotating shaft is matched with the connecting rod to arrange a pressure plate in the limiting groove, the connecting rod at one end of the rotating shaft extends to the interior of the machine box and is sleeved with a first gear, an adjusting knob is arranged on the side wall of the front side of the machine box corresponding to the first gear through a rotating rod, the rotating rod extends to the interior of the machine box and is sleeved with a second gear, the second gear is meshed with the first gear, the first gear and the rotating shaft are driven to rotate by rotating the adjusting knob through the rotating rod and the second gear, so that the locking and the releasing of the display are realized by controlling the overturning of the pressure, avoid it to be damaged breakage by mistake, convenient and practical.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a real-time dynamic monitoring device based on a big data acquisition ward according to the present invention;

FIG. 2 is a diagram of the display roll-over adjustment status of the real-time dynamic monitoring device based on a big data acquisition ward according to the present invention;

FIG. 3 is a schematic view of an upright structure of a display based on a real-time dynamic monitoring device of a big data acquisition ward according to the present invention;

FIG. 4 is an enlarged schematic view of the portion A of FIG. 2 of the real-time dynamic monitoring device for a large data collection-based ward according to the present invention;

FIG. 5 is an exploded view of a case of the real-time dynamic monitoring device based on a big data acquisition ward according to the present invention;

FIG. 6 is a diagram of the internal components of the case of the real-time dynamic monitoring device based on big data acquisition ward of the present invention;

FIG. 7 is a schematic view of an installation structure of a limiting component and an adjusting component of a real-time dynamic monitoring device based on a big data acquisition ward according to the present invention;

FIG. 8 is a schematic structural diagram of a fixer of the real-time dynamic monitoring device based on a big data acquisition ward according to the present invention;

fig. 9 is an enlarged structural schematic view of a locking member of the real-time dynamic monitoring device based on a big data acquisition ward of the invention.

In the figure: 1. a case; 101. a chassis; 102. a circuit board; 103. an MCU module; 104. a data receiving module; 105. a comparison analysis module; 106. an alarm module; 107. a power supply module; 108. a storage module; 109. a wireless connection module; 2. installing a clamping groove; 3. a display; 4. a limiting groove; 5. a limiting component; 51. a rotating shaft; 52. a connecting rod; 53. pressing a plate; 54. a first gear; 6. an adjustment assembly; 61. adjusting a knob; 62. a rotating rod; 63. a second gear; 7. monitoring the detection probe; 8. a holder; 81. a fixing plate; 82. a U-shaped frame; 83. a movable rod; 84. a limiting clamping block; 85. a locking member; 851. a fixed collar; 852. a sleeve; 853. a shaft lever; 854. a connecting spring; 855. a U-shaped clamping strip; 86. clamping the teeth; 87. a snap ring; 9. binding bands; 10. a flat air bag; 11. a function button; 12. a heat dissipation grid; 13. slipping; 14. a connecting rod; 15. and (5) steel balls.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, a real-time dynamic monitoring device based on big data acquisition ward comprises a case 1, an installation slot 2, a display 3, a limit slot 4, a limit component 5, an adjusting component 6, a monitoring detection probe 7, a fixer 8 and a bandage 9, wherein the middle part of the upper end of the case 1 is provided with the installation slot 2, one end of the installation slot 2 extends to the outer wall of one side of the back plate of the case 1, the display 3 is movably clamped and fixed in the installation slot 2, the limit slots 4 are respectively symmetrically arranged at the two side edges of the top port of the installation slot 2, the limit components 5 are respectively arranged between the inner walls of the limit slots 4, the limit components 5 are respectively movably connected with the adjusting components 6 arranged at the two ends of the front side wall of the case 1, the bottom of the case 1 is fixedly connected with the monitoring detection probe 7, the middle part of the side wall of the case 1 at one side of the monitoring detection probe, the fixedly connected with bandage 9 of 1 opposite side outer wall middle part department of machine box that fixer 8 corresponds, the one end block that the machine box 1 was kept away from to bandage 9 is bound machine box 1 in the inside of fixer 8, and still is provided with integrative flat gasbag 10 on the one side outer wall that bandage 9 is close to machine box 1.

The top edges of the machine box 1 outside the limiting grooves 4 are respectively and uniformly provided with a function button 11, the outer walls of the two sides of the machine box 1 are respectively and symmetrically provided with a heat dissipation grid 12, and a dust screen is arranged between the inner walls of the heat dissipation grids 12; corresponding sliding grooves 13 are respectively formed in the inner walls of two sides of the mounting clamping groove 2 at the lower end of the limiting groove 4, connecting rods 14 are respectively and fixedly connected to the outer walls of two sides of the display 3 corresponding to the sliding grooves 13, steel balls 15 are respectively movably sleeved at the tail ends, far away from the side wall of the display 3, of the connecting rods 14, and the steel balls 15 are respectively movably clamped in the inner cavities of the sliding grooves 13.

Referring to fig. 5 and 6, a real-time dynamic monitoring device for a large data collection-based ward, wherein a case 1 has a lower end opening structure, a chassis 101 is sealed at the bottom of the case 1 through a fixing screw, a circuit board 102 is arranged at the upper end of the chassis 101, an MCU module 103, a data receiving module 104, a contrastive analysis module 105, an alarm module 106, a power module 107 and a storage module 108 are respectively and sequentially arranged at the upper end of the circuit board 102, and the MCU module 103, the data receiving module 104, the contrastive analysis module 105, the alarm module 106, the power module 107 and the storage module 108 are electrically connected with each other; the data receiving module 104 is electrically connected with the monitoring detection probe 7 through a wire, when the case 1 is bound on the arm of a patient, the lower end of the monitoring detection probe 7 contacts the arm of the patient to carry out physiological characteristics of the patient, and the monitoring detection probe 7 detects physiological characteristic data including electrocardio, respiration, body temperature, pulse oxygen saturation, pulse rate and non-invasive blood pressure; the circuit board 102 is further provided with a wireless connection module 109, the wireless connection module 109 is electrically connected with the MCU module 103, and the MCU module 103 is connected with a host computer of the nurse station through the wireless connection module 109.

Referring to fig. 2 and 7, a real-time dynamic monitoring device based on a big data acquisition ward, the limiting component 5 includes a rotating shaft 51, a connecting rod 52, a pressing plate 53 and a first gear 54, the connecting rod 52 is symmetrically and fixedly connected to the side walls of the two ends of the rotating shaft 51, the rotating shaft 51 is disposed between the side walls of the limiting groove 4 through the connecting rod 52, the pressing plate 53 is integrally disposed on the outer wall of one side of the rotating shaft 51, the bottom end of the pressing plate 53 is flush with the top end of the display 3 which is horizontally disposed in the mounting slot 2, the end of the connecting rod 52 at one end of the rotating shaft 51 extends into the case 1, the first gear 54 is fixedly connected to the outer wall of the end thereof, only a half circle of teeth is disposed on the outer wall of the first gear 54, and.

Adjusting part 6 includes adjusting knob 61, bull stick 62 and two 63 gears, and adjusting knob 61 laminating sets up on the lateral wall of machine box 1, and the integrative bull stick 62 of fixedly connected with on the one end outer wall of adjusting knob 61, and the one end that adjusting knob 61 was kept away from to bull stick 62 runs through machine box 1 lateral wall and extends to inside, and the fixed cover of the inside bull stick 62 end of machine box 1 has connect two 63 gears, and two gears 63 mesh with a gear 54 mutually.

Referring to fig. 3 and 8, a real-time dynamic monitoring device for a ward based on big data acquisition, the fixer 8 includes a fixing plate 81, a U-shaped frame 82, a movable rod 83, a limiting fixture block 84, a locking member 85, a clamping tooth 86 and a clamping ring 87, the fixing plate 81 is fixedly connected to the middle portion of the front side wall of the case 1, the U-shaped frame 82 is arranged on the side wall of one end of the fixing plate 81, the movable rod 83 is arranged between the side walls of the upper and lower ends of the U-shaped frame 82, the limiting fixture block 84 is arranged on the outer wall of the fixing plate 81 at the movable end of the movable rod 83, the locking member 85 is arranged on the outer wall of one side of the limiting fixture block 84 far away from the fixing plate 81, the movable end of the movable rod 83 is locked by the locking member 85, the clamping tooth 86 is uniformly arranged on the outer.

Please refer to fig. 8 and fig. 9, a real-time dynamic monitor device based on big data acquisition ward, retaining member 85 includes fixed lantern ring 851, sleeve 852, axostylus axostyle 853, coupling spring 854 and U-shaped card strip 855, fixed lantern ring 851 is fixed connection respectively in lower extreme border department on the outer wall of fixed plate 81 one side is kept away from to spacing fixture block 84, sleeve 852 cup joints in the inner chamber of fixed lantern ring 851 through the axostylus axostyle 853 activity of afterbody respectively, and be provided with coupling spring 854 on the inner wall of sleeve 852 corresponding port, two arms of U-shaped card strip 855 are movable respectively and cup joint in the inner chamber of sleeve 852, and the end of U-shaped card strip 855 support arm is fixed continuous with.

In summary, the following steps: the invention provides real-time dynamic monitoring equipment based on a big data acquisition ward, a movable rod 83 is arranged at the middle part of the side wall of the front face of a machine box 1 by utilizing a fixed plate 81 to be matched with a U-shaped frame 82, a limit fixture block 84 is arranged on the outer wall of the fixed plate 81 at the movable end of the movable rod 83 to be clamped with the movable end of the movable rod 83, clamping teeth 86 and clamping rings 87 are respectively arranged on the outer walls of two sides of the movable rod 83, a locking member 85 is arranged on the outer wall of one side, far away from the fixed plate 81, of the limit fixture block 84, a U-shaped clamping strip 855 is arranged by utilizing a fixed lantern ring 851, a sleeve 852, a shaft lever 853 and a connecting spring 854, a binding band 9 arranged at the middle part of the outer wall of the other side of the machine box 1 corresponding to a fixer 8 is clamped by the clamping teeth 86 on the outer wall of the movable rod 83, the movable end of the movable rod, the side with the extra length of the bandage 9 is folded and sleeved in the inner cavity of the clamping ring 87, the tensile force of the bandage 9 is enhanced, the clamping between the clamping teeth 86 and the bandage 9 is strengthened, the monitoring equipment can be quickly worn on an arm for wireless monitoring, and the problem that the use of a traditional monitor circuit is hindered is avoided; the bottom of the case 1 is covered with a chassis 101 through a fixing screw, the lower end of the chassis 101 is provided with a monitoring detection probe 7, an MCU module 103, a data receiving module 104, a contrastive analysis module 105, an alarm module 106, a storage module 108 and a wireless connection module 109 are arranged at the upper end of a chassis 101 by a circuit board 102, physiological characteristic data of a patient monitored by a monitoring detection probe 7 are transmitted to the MCU module 103 through the data receiving module 104, the MCU module 103 calls all stored case information of the patient in the storage module 108 to be contrasted, calculated and analyzed by the contrastive analysis module 105 and put on a screen of a display 3, once the body of the patient is abnormal, the MCU module 103 controls the wireless connection module 109 to be connected with a nurse station host to alarm and call medical care personnel, a doctor can quickly diagnose and judge the state of the patient by looking over the contrasted data on the display 3, and real-time monitoring of the patient is realized by big data contrast; the top of the machine box 1 is provided with a mounting card slot 2 and a limiting slot 4, a display 3 is movably clamped in the inner cavity of the mounting card slot 2 through a sliding slot 13 on the side wall of the mounting card slot 2 clamped by a connecting rod 14 and a steel ball 15, a pressure plate 53 is arranged in the limiting slot 4 by matching a rotating shaft 51 with a connecting rod 52, the connecting rod 52 at one end of the rotating shaft 51 extends into the machine box 1 and is sleeved with a first gear 54, an adjusting knob 61 is arranged on the side wall of the front side of the machine box 1 corresponding to the first gear 54 through a rotating rod 62, the rotating rod 62 extends into the machine box 1 and is sleeved with a second gear 63, the second gear 63 is meshed with the first gear 54, the first gear 54 and the rotating shaft 51 are driven to rotate by rotating the adjusting knob 61 through the rotating rod 62 and the second gear 63, thereby controlling the overturning of the pressure plate 53 to realize the locking and the releasing of the display 3, facilitating the adjustment of the, avoid it to be damaged breakage by mistake, convenient and practical.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a real-time dynamic guardianship equipment based on big data acquisition ward, includes machine box (1), installation draw-in groove (2), display (3), spacing groove (4), spacing subassembly (5), adjusting part (6), guardianship test probe (7), fixer (8) and bandage (9), its characterized in that: the middle part of the upper end of the machine box (1) is provided with an installation clamping groove (2), one end of the installation clamping groove (2) extends to the outer wall of one side of a back plate of the machine box (1), a display (3) is movably clamped and fixed in the installation clamping groove (2), limiting grooves (4) are respectively and symmetrically arranged at the edges of two sides of a top port of the installation clamping groove (2), limiting components (5) are respectively arranged between the inner walls of the limiting grooves (4), the limiting components (5) are respectively and movably connected with adjusting components (6) arranged at two ends of the front side wall of the machine box (1), the bottom of the machine box (1) is fixedly connected with a monitoring detection probe (7), a fixer (8) is arranged at the middle part of the side wall of the machine box (1) at one side of the monitoring detection probe (7), a bandage (9) is fixedly connected at the middle part of the outer wall of the other side of the machine box (1) corresponding to the fixer (8), one end of the bandage (9) far away from the machine box, and the outer wall of one side of the binding band (9) close to the case (1) is also provided with an integrated flat air bag (10).

2. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 1, wherein: the top edge of the machine box (1) at the outer side of the limiting groove (4) is respectively and uniformly provided with a function button (11), the outer walls at two sides of the machine box (1) are respectively and symmetrically provided with a heat dissipation grid (12), and a dust screen is arranged between the inner walls of the heat dissipation grids (12); corresponding sliding grooves (13) are formed in the inner walls of the two sides of the mounting clamping groove (2) at the lower end of the limiting groove (4), connecting rods (14) are fixedly connected to the outer walls of the two sides of the display (3) correspondingly to the sliding grooves (13), steel balls (15) are movably sleeved at the tail ends, far away from the side wall of the display (3), of the connecting rods (14), and the steel balls (15) are movably clamped in inner cavities of the sliding grooves (13) respectively.

3. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 1, wherein: the machine box (1) is of a lower end opening structure, the bottom of the machine box (1) is sealed by a chassis (101) through a fixing screw, a circuit board (102) is arranged at the upper end of the chassis (101), an MCU module (103), a data receiving module (104), a contrastive analysis module (105), an alarm module (106), a power module (107) and a storage module (108) are sequentially arranged at the upper end of the circuit board (102), and the MCU module (103), the data receiving module (104), the contrastive analysis module (105), the alarm module (106), the power module (107) and the storage module (108) are electrically connected with one another.

4. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 3, wherein: the data receiving module (104) is electrically connected with the monitoring detection probe (7) through a wire, when the machine box (1) is bound on the arm of a patient, the lower end of the monitoring detection probe (7) is contacted with the arm of the patient to carry out physiological characteristics of the patient, and the monitoring detection probe (7) detects physiological characteristic data including electrocardio, respiration, body temperature, pulse oxygen saturation, pulse rate and non-invasive blood pressure.

5. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 3, wherein: the circuit board (102) is also provided with a wireless connection module (109), the wireless connection module (109) is electrically connected with the MCU module (103), and the MCU module (103) is connected with a host computer of the nurse station through the wireless connection module (109).

6. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 1, wherein: spacing subassembly (5) are including pivot (51), connecting rod (52), clamp plate (53) and gear (54), symmetry fixedly connected with connecting rod (52) respectively on the both ends lateral wall of pivot (51), pivot (51) pass through connecting rod (52) and set up between the lateral wall of spacing groove (4), and be provided with integrative clamp plate (53) on the outer wall of one side of pivot (51), the bottom of clamp plate (53) is parallel and level with the display (3) top end of arranging in installation draw-in groove (2) in the parallel and level, the end of connecting rod (52) of pivot (51) one end extends to inside machine box (1), fixedly connected with integrative gear (54) on its terminal outer wall, only set up half a circle of rodent on the outer wall of gear (54), and gear (54) link to each other with adjusting part (6) activity.

7. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 1, wherein: adjusting part (6) include adjust knob (61), bull stick (62) and gear two (63), adjust knob (61) laminating sets up on the lateral wall of machine box (1), fixedly connected with integrative bull stick (62) on the one end outer wall of adjust knob (61), the one end that adjust knob (61) were kept away from in bull stick (62) runs through machine box (1) lateral wall and extends to inside it, and the terminal fixed cover of bull stick (62) of machine box (1) inside has connect gear two (63), gear two (63) and gear one (54) mesh mutually.

8. A big data collection ward-based real-time dynamic monitoring device as claimed in claim 1, wherein: the fixer (8) comprises a fixed plate (81), a U-shaped frame (82), a movable rod (83), a limiting clamping block (84), a locking member (85), a clamping tooth (86) and a clamping ring (87), the fixed plate (81) is fixedly connected with the middle part of the front side wall of the case (1), and be provided with U type frame (82) on the lateral wall of fixed plate (81) one end, be provided with movable rod (83) between the lateral wall of U type frame (82) lower extreme, be provided with spacing fixture block (84) on the fixed plate (81) outer wall of movable end of movable rod (83), be provided with retaining member (85) on the outer wall of fixed plate (81) one side is kept away from in spacing fixture block (84), retaining member (85) hasp movable rod (83) movable end, chucking tooth (86) evenly set up on the outer wall of movable rod (83) one side near movable rod (83), be provided with snap ring (87) on the outer wall of one side that movable rod (83) correspond chucking tooth (86).

9. A big data collection-based ward real-time dynamic monitoring device as claimed in claim 8, wherein: retaining member (85) are including fixed lantern ring (851), sleeve (852), axostylus axostyle (853), coupling spring (854) and U type card strip (855), fixed lantern ring (851) lower extreme border department on fixed plate (81) one side was kept away from in spacing fixture block (84) outer wall respectively fixed connection, sleeve (852) are cup jointed in the inner chamber of fixed lantern ring (851) through axostylus axostyle (853) activity of afterbody respectively, and be provided with coupling spring (854) on sleeve (852) correspond the inner wall of port, two arms of U type card strip (855) are the activity respectively cup jointed in the inner chamber of sleeve (852), and U type card strip (855) support arm end is fixed continuous with coupling spring (854) respectively.

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