CN116636837A - Neonate transports vibration measurement cap - Google Patents

Abstract

The application discloses a neonate transferring vibration measuring cap, which comprises an elastic cap body, a mounting belt and a vibration measuring component, wherein the mounting belt is arranged on the elastic cap body, the vibration measuring component comprises an acceleration sensor, a PCB (printed circuit board) and a data transmission module, the acceleration sensor is connected with the mounting belt, and the PCB is respectively and electrically connected with the acceleration sensor and the data transmission module. The acceleration sensor can be bound on the head of the neonate through the elastic cap body, so that the vibration value of the neonate can be monitored in the transferring process, when the vibration value is too high, early warning information can be sent to medical staff, and the risk of intracranial hemorrhage of the neonate and unstable physiological state caused by vibration are prevented from being increased due to vibration and jolt in the transferring process.

Description

Neonate transports vibration measurement cap

Technical Field

The application relates to the technical field of neonatal transport, in particular to a neonatal transport vibration measuring cap.

Background

Neonatal transport (neonatal transport, NT) is one of the important working contents of critical neonatal treatment centers (newborn care center, NCC), and aims to safely transport high-risk neonates to neonatal intensive care units (neonatal intensive care unit) of NCC for treatment, so that the role of high-quality sanitary medical resources is fully played.

Given that some hospitals alone cannot offer all levels of perinatal treatment options, interhospital transport of pregnant women and newborns is an important component of daily medical work in all regional perinatal centers and is also an important patient source. Pregnant women with a high risk of complications and a high risk of poor prognosis, or pregnant women whose birth neonates may need intensive care support should even be considered for prenatal referrals.

The newborns are transported on land by special newborns transporting ambulances, the newborns are transported on a small number of newborns by high-speed rail, and the newborns are transported in the air by means of vehicles such as helicopters or fixed wing airplanes. Newborns transported by means of transportation are subjected to excessive environmental stresses during transportation, in particular vibrations, which may lead to an increased risk of intracranial hemorrhage in premature infants of very low birth weight, and methods for reducing vibrations and noise during transportation should be actively sought.

The harm and adverse effects of vibration on the human body have been widely studied and discussed worldwide. Exposure to a vibrating environment can cause adverse reactions to multiple organs and systems of the human body. Other studies have indicated that the cervical shoulder, gastrointestinal system, female genitalia, peripheral veins and cochlear vestibular system are also affected by vibrations, which may affect the lumbar spine and its associated central nervous system, causing damage to the body. The impact of vibrations on the body is complex and may depend on the amplitude, frequency, direction, duration of the vibrations, and the body part to which the vibrations are directed.

Currently, most research focuses on the physiological condition of workers who are engaged in mechanical and transportation work, and who are exposed to vibration for a long period of time. They may experience fatigue, loss of balance, reduced concentration, reduced comfort and health risks when exposed to vibration. Vibrations may affect certain organs at certain specific amplitudes or frequencies.

However, when the influence of vibration on the newborn is concerned, a great deal of research has yet to be done. Current research on vibration is focused mainly on detecting vibration of a building or workplace. If we want to evaluate the effects of vibrations in the neonatal treatment environment, the available information is very limited.

In the real world, vibrations are ubiquitous, and it is impossible for anyone to avoid exposure to vibrations. Vibration exposure may occur in a work scene, on the way between home and workplace, and in recreational activities.

Since the beginning of the 20 th century, the effects of vibration on the human body have been a continuing research direction. It is well known that any form of vehicle exposes humans to some degree of mechanical vibration, which is defined as whole body vibration (whole body vibration, WBV). The deleterious effects of WBV and its effects on humans are studied and documented throughout the world.

WBV exposure can lead to large differences in biological effects between subjects. In most cases, lumbar exposure may affect the lumbar spine and associated nervous system. Other studies emphasize that neck and shoulder, gastrointestinal system, female reproductive organs, peripheral veins and cochlear-vestibular system are also considered to be affected by WBV.

The effect of vibrations on the human body is very complex, depending at least on the amplitude, direction, frequency, duration of the vibrations and the location where it is directed towards the body. Previous studies on WBV have included, among the important components, the measurement and analysis of vibration exposure levels and health concerns for various work environments, machines and equipment.

Vibration exposure in the environment has a negative impact on the health of both pregnant women and fetuses. There are studies showing that WBV has a detrimental effect on the health of pregnant women, which found that the risk of premature birth and menstrual disorder in some women is high, attributable to prolonged exposure to vibratory environments, and that no safe exposure limits are established, vibration exposure should be avoided or reduced as much as possible during pregnancy to prevent the health of pregnant women from being adversely affected by vibration factors during perinatal periods. Furthermore, studies have shown that exposure of pregnant women to WBV in private automobiles and public transportation may lead to physical discomfort such as spinal pain, abdominal discomfort, dizziness and headache.

Currently, in neonatal treatment, there is often a need to involve intrahospital neonatal transport (i.e., delivery room to NICU or NICU to operating room, etc.), as well as interhospital neonatal transport between different medical institutions. There are many vibration exposures in neonatal care settings, both in transit, which are present in hospitals, and during transit, which are also present between hospitals. Exposure to WBV is a physical hazard that can adversely affect perinatal newborns. It is therefore necessary to attempt to conduct a measurement analysis of WBV to investigate exposure to vibrations to which the neonate is exposed during transport.

Accordingly, the prior art is in need of improvement.

Disclosure of Invention

The application aims to provide a neonate transportation vibration measuring cap, and aims to solve the technical problem that in the prior art, a neonate can be influenced by excessive environmental pressure in the transportation process, particularly vibration, and the risk of intracranial hemorrhage of a premature infant with extremely low birth weight is increased.

In order to achieve the above purpose, the application adopts the following technical scheme:

the application provides a neonate transport vibration measurement cap, comprising:

an elastic cap body;

the mounting belt is arranged on the elastic cap body;

the vibration measuring component comprises an acceleration sensor, a PCB and a data transmission module, wherein the acceleration sensor is connected to the mounting belt, and the PCB is respectively and electrically connected with the acceleration sensor and the data transmission module.

In one embodiment, the system further comprises an alarm device, wherein the alarm device is connected to the PCB, the acceleration sensor is used for detecting the vibration value of the patient, and the alarm device is used for giving an alarm reminding when the vibration value of the patient is higher than a preset value.

In one embodiment, the alarm device comprises one of the following structures:

an audible and visual alarm or a buzzer alarm.

In one embodiment, the acceleration sensor includes the following structure: a triaxial acceleration sensor.

In one embodiment, the data transmission module includes a data line assembly for connecting the PCB and the display screen.

In one embodiment, the data transmission module includes a wireless transmission module, and the wireless transmission module is used for connecting the PCB board and the display screen.

In one embodiment, the wireless transmission module includes at least one of the following structures:

bluetooth module, wifi module, 4G module or 5G module.

In one embodiment, the elastic cap body includes:

the net-shaped elastic structure is provided with the mounting belt;

the material of the reticular elastic structure comprises one of the following structures:

elastic nylon or elastic gauze.

In one embodiment, the mounting band is located at an opening position of the elastic cap body, and the mounting band is provided as an elastic endless band including:

the ring belt body is arranged on the elastic cap body;

the fixing seat is arranged on the annular belt body and is used for installing the vibration measuring component.

The neonate transport vibration measuring cap provided by the application has the beneficial effects that:

the application discloses a neonate transfer vibration measurement cap, which comprises an elastic cap body, a mounting belt and a vibration measurement component, wherein the mounting belt is arranged on the elastic cap body, the vibration measurement component comprises an acceleration sensor, a PCB (printed circuit board) and a data transmission module, the acceleration sensor is connected with the mounting belt, and the PCB is respectively and electrically connected with the acceleration sensor and the data transmission module. The acceleration sensor can be bound on the head of the neonate through the elastic cap body, so that the vibration value of the neonate can be monitored in the transferring process, when the vibration value is too high, early warning information can be sent to medical staff, the speed and driving mode of an ambulance can be reduced, and the increase of the sick risk of intracranial hemorrhage of the neonate due to vibration jolt and the unstable physiological state caused by vibration can be prevented.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments or the description of the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic view of a neonatal transport vibration measurement cap according to an embodiment of the present application;

FIG. 2 is a schematic diagram of a vibration measuring component according to an embodiment of the present application;

FIG. 3 is a schematic view of a first embodiment of a neonatal transport vibration measurement cap according to an embodiment of the present application;

FIG. 4 is a second schematic structural view of an embodiment of a neonatal transport vibration measurement cap according to an embodiment of the present application;

fig. 5 is a schematic structural view III of a specific embodiment of a neonatal transport vibration measurement cap according to an embodiment of the present application.

Wherein, each reference sign in the figure:

100. an elastic cap body; 200. a mounting belt; 300. a vibration measuring part; 400. an alarm device; 500. a terminal device; 110. a net-like elastic structure; 120. an elastic cushion layer; 210. an endless belt body; 220. a fixing seat; 230. a magic tape; 240. a shrinkage opening is formed; 250. a tether; 310. an acceleration sensor; 320. a PCB board; 330. and a data transmission module.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly or indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly or indirectly connected to the other element. The directions or positions indicated by the terms "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. are directions or positions based on the drawings, and are merely for convenience of description and are not to be construed as limiting the present technical solution. The terms "first," "second," and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. The meaning of "a plurality of" is two or more, unless specifically defined otherwise.

Referring to fig. 1 and 2, the present embodiment provides a neonatal transport vibration measurement cap, which includes: the vibration measuring device comprises an elastic cap body 100, a mounting belt 200 and a vibration measuring component 300, wherein the mounting belt 200 is arranged on the elastic cap body 100, the vibration measuring component 300 comprises an acceleration sensor 310, a PCB 320 and a data transmission module 330, the acceleration sensor 310 is connected to the mounting belt 200, and the PCB 320 is electrically connected with the acceleration sensor 310 and the data transmission module 330 respectively.

In this embodiment, this neonate transports vibration measurement cap is used for neonate's transportation to real-time supervision neonate's vibration condition in transportation process is used for avoiding neonate's intracranial hemorrhage or other physiological condition unstability because of vibration appear in transportation process, guarantees neonate's transportation in-process infant safety. The elastic cap body 100 is used for being worn on the head of a neonate, the installation belt 200 is located on the elastic cap body 100, the installation belt 200 can be set to be a closed ring belt for binding the vibration measuring component 300 on the head of the neonate, the PCB board 320 is electrically connected with the acceleration sensor 310 and the data transmission module 330 respectively, the acceleration sensor 310 is used for monitoring the vibration value of the head of the neonate in real time, the acceleration sensor 310 transmits the monitored vibration value to the PCB board 320, and the PCB board 320 can send the vibration value to the terminal device 500 through the data transmission module 330. The terminal device 500 may be a monitor or a mobile phone APP. The monitor and the mobile phone APP can be understood as the prior art, so the specific structures of the monitor and the mobile phone APP are not described herein.

Referring to fig. 2, the neonate transfer vibration measurement cap may include an elastic cap body 100, a mounting belt 200, a vibration measurement part 300 and an alarm device 400, wherein the vibration measurement part 300 includes an acceleration sensor 310, a PCB board 320 and a data transmission module 330, the alarm device 400 is connected to the PCB board 320, the acceleration sensor 310 is used for detecting a vibration value of a patient, and when the vibration value of the patient is higher than a preset value, the alarm device 400 is used for giving an alarm. For example, when the neonate is in the process of transferring, the neonate transferring vibration measuring cap is worn on the head of the neonate, and if the neonate is excessively vibrated, the alarm device 400 can send out an alarm to prevent the neonate from being excessively vibrated during the transferring process. Of course, the alarm device 400 can be connected with a button for suspending the alarm or closing the alarm function, the alarm device 400 can also be arranged on the monitor or the mobile phone APP, when the monitored vibration value is sent to the monitor or the mobile phone APP through the data transmission module 330, the monitor or the mobile phone APP can send out an alarm prompt.

Alternatively, the alarm device 400 may include one of the following structures:

an audible and visual alarm or a buzzer alarm.

For example, the alarm device 400 may include an audible and visual alarm that may sound an audible and visual alarm to prevent intracranial hemorrhage in the neonate during transportation if the neonate is subjected to excessive vibration.

For example, the alarm device 400 may include a buzzer alarm that may sound a buzzer alarm if the neonate is subjected to excessive vibration to avoid intracranial hemorrhage during transportation.

Alternatively, the acceleration sensor 310 includes the following structure: a three-axis acceleration sensor 310.

The acceleration sensor 310 in this embodiment may adopt a triaxial acceleration sensor 310, where the triaxial acceleration sensor 310 is based on the basic principle of acceleration to implement work, and has the characteristics of small volume and light weight, and can measure spatial acceleration, and can fully and accurately reflect the motion properties of an object. For example, the present embodiment is used to monitor vibration values of the head of the neonate in real time through the triaxial acceleration sensor 310.

Referring to fig. 3, the mounting band 200 is located at an opening position of the elastic cap body 100, and the mounting band 200 is configured as an elastic endless band, which includes: the vibration measuring device comprises an annular belt body 210 and a fixing seat 220, wherein the annular belt body 210 is arranged on the elastic cap body 100, the fixing seat 220 is arranged on the annular belt body 210, and the fixing seat 220 is used for installing the vibration measuring component 300.

In this embodiment, the mounting belt 200 is located at the opening position of the elastic cap body 100, the elastic cap body 100 is used to be sleeved on the head of the neonate, when the elastic cap body 100 is sleeved on the head of the neonate, the mounting belt 200 is located at the forehead position of the neonate, the mounting belt 200 is provided as an elastic ring belt, that is, the elastic cap body 100 is fastened on the forehead of the neonate through the elastic ring belt, the acceleration sensor 310 is connected to the mounting belt 200, that is, the acceleration sensor 310 is fixed at the forehead position of the neonate through the elastic ring belt, so that the phenomenon of falling off in the process of transferring vibration is prevented. Wherein, the elastic endless belt includes: the annular belt body 210 and the fixing seat 220, when the elastic cap body 100 is sleeved on the head of the neonate, the annular belt body 210 is used for being elastically connected to the forehead of the neonate, the fixing seat 220 is used for installing the acceleration sensor 310 and the PCB 320, so that the vibration measuring part 300 is fixed on the forehead of the neonate, and damage to the neonate caused by the vibration measuring part 300 in the vibration process is avoided. The elastic cap 100 cooperates with the elastic band without wrapping the chin and cheeks (wrapping the chin is clinically risky) and the neonate sometimes needs to breathe orally. The appearance of the neonate transferring vibration measuring cap is consistent with that of a common cap, the neonate transferring vibration measuring cap has comfortableness, can play a role in keeping warm, can fade the measurement in appearance, and is easy to accept by a family and a neonate.

For example, the elastic cap body 100 is provided with an elastic ring belt at an opening position, the elastic ring belt is provided with a fixing seat 220, the fixing seat 220 may include a fixing bag, that is, the elastic ring belt is provided with a fixing bag for mounting the vibration measuring part 300, the elastic cap body 100 is worn on the head of the neonate, the elastic ring belt is located on one side of the forehead of the neonate, and the fixing bag can be used for conveniently mounting or dismounting the vibration measuring part 300. In order to improve the fit degree of the neonate transfer vibration measurement cap and the neonate, one side of the elastic annular belt can be provided with a magic tape 230, the magic tape 230 is provided with a hook surface, the elastic annular belt is provided with a hair surface matched with the hook surface, after the elastic cap body 100 wears the head of the neonate, the hook surface and the hair surface of the elastic cap body 100 can be closed for further fitting the elastic cap body 100 on the head of the neonate, and falling-off phenomenon in the vibration process is prevented.

Alternatively, referring to fig. 4, in order to improve the fit of the neonate transfer vibration measurement cap to the neonate, a tightening opening 240 may be provided on the elastic ring belt, a tether 250 may be provided in the tightening opening 240, the elastic cap body 100 may be tied to the head of the neonate through the tether 250, and the acceleration sensor 310 may be fixed to the forehead of the neonate.

Referring to fig. 1, the elastic cap body 100 includes: the net elastic structure 110, the net elastic structure 110 is provided with the mounting band 200.

For example, the elastic cap body 100 may include: a net-like elastic structure 110. The mesh elastic structure 110 has good elasticity and breathability, can be effectively worn on the head of a newborn, and can improve comfort during transportation.

Optionally, the material of the mesh elastic structure 110 includes one of the following structures:

elastic nylon or elastic gauze.

For example, the material of the mesh elastic structure 110 may be made of elastic nylon.

Alternatively, the material of the mesh elastic structure 110 may be made of elastic gauze.

Referring to fig. 5, in order to improve wearing comfort, an elastic cushion layer 120, such as a foam layer or a sponge layer, may be disposed on the mesh elastic structure 110, for example, a foam layer may be disposed on the mesh elastic structure 110, when the neonate's transfer vibration measurement cap is worn on the neonate's head, the foam layer is attached to the neonate's scalp, and the foam layer (such as EVA plastic) has good softness and elasticity, so that wearing comfort can be improved.

Optionally, referring to fig. 1 and 2, the data transmission module 330 may include a data line assembly or a wireless transmission module, where the data line assembly and the wireless transmission module are used to connect the PCB 320 and the display screen.

For example, the data transmission module 330 may include a data line assembly, and the PCB 320 may be electrically connected to the terminal device 500 through the data line assembly to transmit the vibration value to the terminal device 500.

Alternatively, the data transmission module 330 may include a wireless transmission module, and the PCB 320 may wirelessly transmit the vibration value to the terminal device 500 through the wireless transmission module.

Optionally, the wireless transmission module may include at least one of the following structures:

bluetooth module, wifi module, 4G module or 5G module.

For example, the PCB 320 may be wirelessly transmitted to the terminal 500 through the bluetooth module, so as to transmit the vibration value to the terminal 500, for example, the terminal 500 may have a display screen, and the vibration value may be displayed in real time through the display screen, and if the vibration value exceeds a preset value, the terminal 500 may issue an alarm.

For example, the PCB 320 may be wirelessly transmitted to the terminal 500 through the Wifi module, so as to transmit the vibration value to the terminal 500, for example, the terminal 500 may have a display screen, and the vibration value may be displayed in real time through the display screen, and if the vibration value exceeds a preset value, the terminal 500 may issue an alarm.

For example, the PCB 320 may be wirelessly transmitted to the terminal 500 through the 4G module or the 5G module, so as to transmit the vibration value to the terminal 500, for example, the terminal 500 may have a display screen, and the vibration value may be displayed in real time through the display screen, and if the vibration value exceeds a preset value, the terminal 500 may send an alarm to remind.

For example, the PCB 320 may be wirelessly transmitted to the terminal 500 through the bluetooth module, the Wifi module, the 4G module, and the 5G module, so as to transmit the vibration value to the terminal 500, for example, the terminal 500 may have a display screen, and the vibration value may be specifically displayed in real time through the display screen, and if the vibration value exceeds the preset value, the terminal 500 may send an alarm to remind.

Based on the neonatal transport vibration measurement cap in the above embodiment, the neonatal transport vibration measurement cap in this embodiment may be used together with an ambulance, where the ambulance may be understood as the prior art, and the specific structure thereof is not described herein.

In summary, the application discloses a neonate transferring vibration measuring cap, which comprises an elastic cap body, a mounting belt and a vibration measuring component, wherein the mounting belt is arranged on the elastic cap body, the vibration measuring component comprises an acceleration sensor, a PCB (printed circuit board) and a data transmission module, the acceleration sensor is connected with the mounting belt, and the PCB is respectively and electrically connected with the acceleration sensor and the data transmission module. The acceleration sensor can be bound on the head of the neonate through the elastic cap body, so that the vibration value of the neonate can be monitored in the transferring process, when the vibration value is too high, early warning information can be sent to medical staff, and the risk of intracranial hemorrhage of the neonate and unstable physiological state caused by vibration are prevented from being increased due to vibration and jolt in the transferring process.

The foregoing description of the preferred embodiments of the application is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the application.

Claims (9)

1. A neonatal transport vibration measurement cap, comprising:

an elastic cap body;

the mounting belt is arranged on the elastic cap body;

the vibration measuring component comprises an acceleration sensor, a PCB and a data transmission module, wherein the acceleration sensor is connected to the mounting belt, and the PCB is respectively and electrically connected with the acceleration sensor and the data transmission module.

2. The neonatal transport vibration measurement cap of claim 1, further comprising an alarm device connected to the PCB board, the acceleration sensor is configured to detect a vibration value of the patient, and the alarm device is configured to issue an alarm alert when the vibration value of the patient is higher than a preset value.

3. The neonatal transport vibration measurement cap of claim 2, wherein the alarm device comprises one of the following structures:

an audible and visual alarm or a buzzer alarm.

4. The neonatal transport vibration measurement cap of claim 1, wherein the acceleration sensor comprises the following structure: a triaxial acceleration sensor.

5. The neonatal transport vibration measurement cap of claim 1, wherein the data transmission module includes a data line assembly for connecting the PCB board and a display screen.

6. The neonatal transport vibration measurement cap of claim 1, wherein the data transmission module comprises a wireless transmission module for connecting the PCB board and a display screen.

7. The neonatal transport vibration measurement cap of claim 6, wherein the wireless transmission module comprises at least one of the following:

bluetooth module, wifi module, 4G module or 5G module.

8. The neonatal transport vibration measurement cap as set forth in claim 1, wherein the elastomeric cap body comprises:

the net-shaped elastic structure is provided with the mounting belt.

9. The neonatal transport vibration measurement cap as set forth in claim 1, wherein the mounting strap is located at an opening position of the elastic cap body and the mounting strap is provided as an elastic loop band comprising:

the ring belt body is arranged on the elastic cap body;

the fixing seat is arranged on the annular belt body and is used for installing the vibration measuring component.