CN217852948U - Data acquisition equipment - Google Patents

Abstract

The utility model provides a data acquisition equipment, belong to medical equipment technical field, including the casing that has the accommodation space, built-in first controller in the casing, pump valve assembly, the fixed blood pressure data acquisition interface that sets up on the casing, and the fixed other physiological data acquisition interface that sets up on the casing, other physiological data acquisition interfaces are connected with first controller, blood pressure data acquisition interface passes through pump valve assembly and is connected with first controller, through setting up blood pressure data acquisition interface and other physiological data acquisition interface on the casing, make can gather blood pressure data under pump valve assembly's supplementary through the outside blood pressure monitoring equipment with blood pressure data acquisition interface connection, and gather other physiological data through other outside monitoring equipment with other physiological data acquisition interface connection, automatic collection blood pressure data and other physiological data have been realized, thereby the collection efficiency of physiological data has been improved.

Description

Data acquisition equipment

Technical Field

The utility model relates to the technical field of medical equipment, especially, relate to a data acquisition equipment.

Background

In the medical technical field, the physiological parameters of patients are acquired in time, which is very important for monitoring the physical state of the patients. The physiological data of the human body mainly includes blood pressure data and other data, such as blood oxygen data and pulse rate data.

In general, when blood pressure data is collected, blood pressure data of a patient is mainly measured by a blood pressure meter and is manually recorded so as to finish the collection of the blood pressure data; when other physiological data such as blood oxygen data are collected, blood oxygen data of a patient are mainly measured by an oximeter and are manually recorded to complete collection of the blood oxygen data, but the collection efficiency is low due to the adoption of the physiological data collection mode.

Therefore, how to design a portable automatic physiological data acquisition device is a problem to be solved urgently by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

The utility model provides a data acquisition equipment, a collection mode for solving carrying out the collection to physiological data among the prior art, can lead to the lower defect of collection efficiency, through set up blood pressure data acquisition interface and other physiological data acquisition interface on the casing, make can gather blood pressure data under pump valve unit's supplementary through the outside blood pressure monitoring equipment with blood pressure data acquisition interface connection, and gather other physiological data through other outside monitoring equipment with other physiological data acquisition interface connection, automatic blood pressure data and other physiological data of gathering have been realized, thereby physiological data's collection efficiency has been improved.

The utility model provides a data acquisition equipment, be in including casing, the built-in casing that has the accommodation space first controller, pump valve assembly, the fixed setting in the casing are in blood pressure data acquisition interface on the casing to and fixed the setting is in other physiological data acquisition interfaces on the casing, other physiological data acquisition interfaces with first controller is connected, blood pressure data acquisition interface passes through pump valve assembly with first controller is connected.

The pump valve assembly comprises an air pump, an air valve and a pipeline for connecting the air pump and the air valve, and the air valve is fixedly arranged in the accommodating space and close to the blood pressure data acquisition interface and is connected with the blood pressure data acquisition interface; the air pump is fixedly arranged at one side position of the air valve far away from the blood pressure data acquisition interface through a first baffle, a second baffle and a third baffle.

The first baffle is tightly attached to the middle position of one side, far away from the longitudinal section, of the air pump transverse section, the second baffle and the third baffle are respectively tightly attached to the left side and the right side of the air pump longitudinal section, and the end faces, close to one side of the air pump transverse section, of the second baffle and the third baffle are abutted to the air pump transverse section.

According to the utility model provides a pair of data acquisition equipment, the casing includes first casing and sets up the second casing of first casing below, blood pressure data acquisition interface with other physiological data acquisition interfaces are all fixed to be set up the first side of second casing.

Wherein, the other physiological data acquisition interfaces comprise an acquisition interface corresponding to blood oxygen data and/or an acquisition interface corresponding to pulse rate data.

According to the utility model provides a pair of data acquisition equipment, first controller sets up on the base plate, the base plate is fixed to be set up on the second casing, still be provided with the second controller on the base plate, the second controller with first controller interval sets up.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes bar code collector, bar code collector is fixed to be set up the top of second casing, and with the second controller is connected.

The code scanner is used for scanning a two-dimensional code or a bar code of the user identity information and sending the obtained user identity information to the second controller.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes the display screen subassembly, the display screen subassembly is embedded the surface of first casing, the display screen subassembly includes display screen and touch-sensitive screen, the display screen with the touch-sensitive screen all with the second controller is connected.

The touch screen is used for detecting a touch signal of a user and sending the touch signal to the second controller.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes the speaker, the speaker is fixed to be set up on the second casing, and with the second controller is connected.

The loudspeaker is used for outputting prompt information.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment is still including the draw-in groove that is used for holding user identification card, the draw-in groove is external the second side of second casing, and with the second controller is connected.

The card slot is used for providing a mobile network for the data acquisition equipment through the user identification card.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes universal serial bus interface, universal serial bus interface is external the second side of second casing, and with the second controller is connected.

The universal serial bus interface is used for being connected with an external power supply device to supply power to the data acquisition device through the external power supply device, or used for being connected with an external expansion device to receive a control signal of the external expansion device, or used for being connected with other electronic devices to transmit acquired physiological data to the other electronic devices.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes the on & off button, the on & off button is fixed to be set up the second side of second casing, and with the second controller is connected.

The power on/off button is used for receiving pressing operation of a user on the power on/off button.

According to the utility model provides a pair of data acquisition equipment, data acquisition equipment still includes the battery, the battery fixed set up in below in the accommodation space is regional, and with first controller reaches the second controller is connected.

The battery is used for supplying power to the first controller and the second controller.

The utility model provides a pair of data acquisition equipment, through set up on the casing blood pressure data acquisition interface reaches other physiological data acquisition interfaces for can through with the outside blood pressure monitoring equipment of blood pressure data acquisition interface connection gather blood pressure data under the assistance of pump valve subassembly, and gather other physiological data through other outside monitoring equipment with other physiological data acquisition interface connection, realize automatic blood pressure data and other physiological data of gathering, thereby improved physiological data's collection efficiency; in addition, by arranging the pump valve assembly, air pressure can be provided when external monitoring equipment is used for detecting the blood pressure of a patient, and an air pressure source does not need to be additionally carried or the pressure is increased manually; in addition, the air pump is fixed through the first baffle, the second baffle and the third baffle, so that the horizontal shaking of the air pump is inhibited, and the vertical shaking of the air pump is also inhibited.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the following briefly introduces the drawings required for the embodiments or the prior art descriptions, and obviously, the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of an overall structure of a data acquisition device provided by the present invention;

fig. 2 is a schematic connection diagram of a data acquisition device provided by the present invention;

fig. 3 is a schematic structural diagram of an installation state of a second housing of the data acquisition device provided by the present invention;

fig. 4 is a schematic view of an installation structure of an air pump of the data acquisition device provided by the present invention;

fig. 5 is a schematic exploded view of a data acquisition device provided by the present invention;

fig. 6 is a schematic structural diagram of a second housing of the data acquisition device provided by the present invention;

fig. 7 is a second schematic connection diagram of the data acquisition device provided by the present invention;

fig. 8 is a schematic view of the overall structure of another view angle of the data acquisition device provided by the present invention.

Reference numerals:

101. a housing; 102. a blood pressure data acquisition interface; 103. other physiological data acquisition interfaces; 104. an air pump; 105. an air valve; 106. a first baffle plate; 107. a second baffle; 108. a third baffle; 109. a first housing; 110. a second housing; 111. a blood oxygen data acquisition interface; 112. a substrate; 113. a first fixed column; 114. a first positioning post; 115. a second positioning column; 116. a third positioning column; 117. a fourth positioning column; 118. a fifth positioning column; 119. a sixth positioning column; 120. a first accommodating portion; 121. a second accommodating portion; 122. a fourth baffle; 123. A fifth baffle; 124. a code scanner; 125. a first tablet; 126. a second tabletting; 127. thirdly, tabletting; 128. a fourth tabletting; 129. a power-on and power-off button; 130. a card slot; 131. a universal serial bus interface; 132. a display screen assembly; 133. a light guide pillar; 134. a speaker; 135. A battery; 136. a first controller; 137. a second controller; 138. a pump valve assembly; 139. A data transmission module; 140. and (4) storing the card.

Detailed Description

To make the objects, technical solutions and advantages of the present invention clearer, the drawings in the present invention will be combined to clearly and completely describe the technical solutions of the present invention, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The data acquisition device of the present invention is described below with reference to fig. 1-8.

The physiological data of the human body mainly includes blood pressure data and other data, such as blood oxygen data and pulse rate data. In the prior art, when blood pressure data is collected, a blood pressure meter is mainly adopted to measure the blood pressure data of a patient and manually record the blood pressure data so as to finish the collection of the blood pressure data; when other physiological data such as blood oxygen data are collected, blood oxygen data of a patient are mainly measured by an oximeter and are manually recorded to complete collection of the blood oxygen data, but the collection efficiency is low due to the adoption of the physiological data collection mode. Therefore, the utility model provides an automatic physiological data acquisition equipment.

Exemplarily, fig. 1 is the utility model provides an overall structure schematic diagram of data acquisition equipment, fig. 2 is the utility model provides a data acquisition equipment's one of the connection schematic diagram, it is shown with fig. 2 to combine, the utility model provides a data acquisition equipment, including casing 101, the first controller 136 that have the accommodation space, pump valve subassembly 138, the fixed blood pressure data acquisition interface 102 that sets up on casing 101 to and the fixed other physiological data acquisition interface 103 that set up on casing 101, other physiological data acquisition interfaces 103 are connected with first controller 136, and blood pressure data acquisition interface 102 is connected with first controller 136 through pump valve subassembly 138.

The blood pressure data collecting interface 102 is mainly used for collecting blood pressure data collected by an external blood pressure monitoring device connected to the blood pressure data collecting interface 102 with the aid of the pump valve assembly 138, and sending the blood pressure data to the first controller 136.

The other physiological data collecting interface 103 is mainly configured to collect other physiological data collected by other external monitoring devices connected to the other physiological data collecting interface 103, and send the other physiological data to the first controller 136. For example, the other physiological data may include blood oxygen data and/or pulse rate data, and of course, may also include other physiological data, and may be specifically set according to actual needs, and herein, the embodiment of the present invention is only described by taking the example that the other physiological data includes blood oxygen data and/or pulse rate data, but the present invention is not limited thereto.

In order to facilitate understanding of the present invention, the utility model provides a pump valve assembly 138 structure, exemplarily, can refer to fig. 3 and fig. 4 and show, fig. 3 is the utility model provides a mounting state structure schematic diagram of data acquisition equipment's second casing, fig. 4 is the utility model provides a mounting structure schematic diagram of data acquisition equipment's air pump, wherein, pump valve assembly 138 includes air pump 104, pneumatic valve 105 and connects the pipeline of air pump 104 and pneumatic valve 105, pneumatic valve 105 is fixed to be set up in the accommodation space near the position of blood pressure data acquisition interface 102, and is connected with blood pressure data acquisition interface 102, and air pump 104 is T type structure, and air pump 104 is fixed to be set up in one side position that blood pressure data acquisition interface 102 was kept away from to pneumatic valve 105 through first baffle 106, second baffle 107 and third baffle 108.

The air pump 104 is an air pump, and in the present invention, is an electric air pump, which compresses air by electric power to generate air pressure.

The air valve 105 is a valve installed on the air path, and is used for controlling the opening and closing of the air path, opening the air path when acquiring the physiological data of blood pressure, and providing air pressure to the corresponding external monitoring equipment through an acquisition interface corresponding to the physiological data of blood pressure, so that the external monitoring equipment monitors the physiological data of blood pressure through the air pressure.

It can be seen that the pump valve assembly 138 is arranged in the data acquisition equipment, so that air pressure can be provided when external monitoring equipment is used for detecting the blood pressure of a patient, and an air pressure source does not need to be additionally carried or the pressure is manually increased; in addition, the air pump 104 and the air valve 105 are designed tightly, so that the length of an air path pipeline is reduced, the consumption of materials is reduced, the cost is reduced, the electromagnetic compatibility can be enhanced by reducing the wire length, the loop area is reduced, and the volume of data acquisition equipment is reduced.

Further, in order to mount the air pump 104 in the housing 101 more stably, as shown in fig. 4, the first baffle 106 is tightly attached to the middle position of the side of the transverse section of the air pump 104 away from the longitudinal section, the second baffle 107 and the third baffle 108 are respectively tightly attached to the left and right sides of the longitudinal section of the air pump 104, and the end surfaces of the second baffle 107 and the third baffle 108 close to the side of the transverse section of the air pump 104 are abutted to the transverse section of the air pump 104.

It can be seen that, the mode of fixing the air pump 104 by the first baffle 106, the second baffle 107 and the third baffle 108 not only inhibits the horizontal shaking of the air pump 104, but also inhibits the vertical shaking of the air pump 104, and by adopting the fixing mode, the number of the baffles is reduced, the processing cost is reduced, and meanwhile, the overall weight of the data acquisition equipment is reduced, so that the data acquisition equipment is more portable. Furthermore, in the present invention, in order to reduce the vibration intensity of the air pump 104 and achieve the effect of reducing the vibration sound, a flexible gasket is disposed at the bottom of the air pump 104 and the air valve 105.

It can be seen that the utility model provides a data acquisition device, through set up blood pressure data acquisition interface 102 and other physiological data acquisition interface 103 on casing 101 for can gather blood pressure data under the assistance of pump valve subassembly 138 through the external blood pressure monitoring equipment who is connected with blood pressure data acquisition interface 102, and gather other physiological data through other external monitoring equipment who is connected with other physiological data acquisition interface 103, realize automatic collection blood pressure data and other physiological data, thereby improved physiological data's collection efficiency; in addition, by arranging the pump valve assembly 138, air pressure can be provided when external monitoring equipment is used for detecting the blood pressure of a patient, and an air pressure source does not need to be additionally carried or the pressure is increased manually; in addition, the air pump 104 is fixed through the first baffle 106, the second baffle 107 and the third baffle 108, so that the horizontal shaking of the air pump 104 is restrained, and the vertical shaking of the air pump 104 is restrained.

In a possible scenario, based on the above embodiment shown in fig. 1 and fig. 2, in order to facilitate installation and maintenance of the data acquisition device, as shown in fig. 5, fig. 5 is a schematic explosion diagram of the data acquisition device provided by the present invention, the housing 101 is set to be a split structure, the housing 101 includes a first housing 109 and a second housing 110 disposed below the first housing 109, the blood pressure data acquisition interface 102 and the other physiological data acquisition interfaces 103 are both fixedly disposed on a first side of the second housing 110, and the other physiological data acquisition interfaces 103 include an acquisition interface corresponding to blood oxygen data and/or an acquisition interface corresponding to pulse rate data. Illustratively, in the present embodiment, the blood oxygen data acquisition interface may be labeled 111.

In order to facilitate understanding of the fixing manner between the first casing 109 and the second casing 110, fig. 6 is a schematic structural diagram of the second casing of the data acquisition device, which is shown in fig. 6, four first fixing columns 113 are arranged at four corners inside the second casing 110, four first fixing plates arranged in cooperation with the first fixing columns 113 are arranged at four corners inside the first casing 109, the first casing 109 and the second casing 110 are fixedly connected in cooperation with the first fixing plates through the first fixing columns 113, and the first casing 109 and the second casing 110 jointly enclose an accommodating space.

It can be seen that, the housing 101 is designed as a split structure, when the data acquisition device is installed or maintained, the first housing 109 and the second housing 110 can be separated, so as to facilitate the installation or maintenance of the data acquisition device, and after the installation or maintenance is completed, the first housing 109 and the second housing 110 are fixedly connected; in addition, the blood pressure data acquisition interface 102 and other data acquisition interfaces are arranged on the first side face, so that the relevant accessories can be conveniently plugged and pulled out, and wires of the relevant accessories can be conveniently arranged.

For example, as shown in fig. 6, when the blood oxygen monitoring device is connected to the blood oxygen data collecting interface 111, in order to make the connection relationship more stable and avoid the connection relationship from shaking, two fifth positioning pillars 118 may be respectively disposed at two ends of the blood oxygen data collecting interface 111 inside the second housing 110, and the two fifth positioning pillars 118 are fixedly connected to the portion of the blood oxygen data interface extending into the second housing 110.

To further understand the installation manner of the pump and valve assembly 138 in the present embodiment, as shown in fig. 6, the pump and valve assembly 138 is disposed in the upper area of the accommodating space inside the second housing 110, two second positioning pillars 115 are disposed inside the second housing 110 and near the blood pressure collecting interface, a first accommodating portion 120 is disposed between the two second positioning pillars 115, the shape of the first accommodating portion 120 is matched with the shape of the air valve 105, the air valve 105 is disposed in the first accommodating portion 120, two third positioning pillars 116 are disposed on one side of the air valve 105 away from the blood pressure data collecting interface 102, and the air pump 104 is disposed between the two third positioning pillars 116.

For example, in order to mount the air pump 104 and the air valve 105 more stably and prevent the air valve 105 and the air pump 104 from shaking, as shown in fig. 3, a first pressing piece 125 is disposed on the top of the air valve 105, a second pressing piece 126 is disposed on the top of the air pump 104, the first pressing piece 125 is pressed against the top surface of the air valve 105, two ends of the first pressing piece 125 are fixedly connected to the tops of the two second positioning posts 115, the second pressing piece 126 is pressed against the top surface of the air pump 104, and two ends of the second pressing piece 126 are fixedly connected to the tops of the two third positioning posts 116.

The heights of the two second positioning posts 115 are slightly lower than the height of the air valve 105, and the heights of the two third positioning posts 116 are slightly lower than the height of the air pump 104.

It can be seen that, under the condition that the heights of the two second positioning columns 115 are slightly lower than the height of the air valve 105 and the heights of the two third positioning columns 116 are slightly lower than the height of the air pump 104, two ends of the first pressing piece 125 are connected with the two second positioning columns 115, two ends of the second pressing piece 126 are connected with the two third positioning columns 116, two ends of the first pressing piece 125 are lower than the air valve 105, two ends of the second pressing piece 126 are lower than the air pump 104, the middle part of the first pressing piece 125 is located on the top surface of the air valve 105, the middle part of the second pressing piece 126 is located on the top surface of the air pump 104, and under the elastic action of the first pressing piece 125 and the second pressing piece 126, pressure is applied to the top surfaces of the air valve 105 and the air pump 104 to press the air valve 105 and the air pump 104 tightly, so that the installation of the air valve 105 and the air pump 104 is more stable and is not easy to shake.

In a possible scenario, based on the above embodiment shown in fig. 5, in order to avoid that a plurality of substrates occupy the space in the housing 101, and reduce the volume of the data acquisition device, referring to fig. 7, fig. 7 is a second schematic connection diagram of the data acquisition device provided by the present invention, the first controller 136 is disposed on the substrate 112, and the substrate 112 is fixedly disposed on the second housing 110, and the second controller 137 is further disposed on the substrate 112, and the first controller 136 and the second controller 137 are disposed at intervals.

The first controller 136 is connected to the blood pressure data acquisition interface 102 and the other physiological data acquisition interfaces 103, and is responsible for processing the physiological parameters in the form of analog signals acquired through the blood pressure data acquisition interface 102 and the other physiological data acquisition interfaces 103 to obtain corresponding physiological data in the form of digital signals; the second controller 137 is mainly used for processing the physiological parameter in the form of a digital signal, and the processing includes storing the physiological parameter of the digital signal locally or uploading the physiological parameter to other electronic devices.

For example, as shown in fig. 3 and fig. 6, when the substrate 112 is mounted inside the second casing 110, four first positioning posts 114 may be disposed inside the second casing 110 at positions close to the bottom, the substrate 112 is fixedly connected to the tops of the four first positioning posts 114, and the substrate 112 is fixedly mounted on the second casing 110 by using screws to pass through the positioning holes on the substrate 112 to connect to the first positioning posts 114.

It can be seen that in the embodiment of the present invention, the first controller 136 and the second controller 137 are both disposed on one substrate 112, and the substrate 112 is mounted on the top of the first positioning column 114 through screws, compared with the prior art, the first controller 136 and the second controller 137 are respectively mounted on one substrate 112, so as to reduce the number of the substrates 112, thereby avoiding the plurality of substrates 112 occupying the space in the housing 101, and reducing the volume of the data acquisition device.

Illustratively, when the first controller 136 and the second controller 137 are arranged at intervals, in order to avoid that the high-frequency signal generated by the second controller 137 influences the analog signal of the blood pressure blood oxygen part received by the first controller 136 when the first controller 136 and the second controller 137 are communicated, an isolation strip may be arranged between the second controller 137 and the first controller 136, and the first controller 136 and the second controller 137 are arranged at intervals by the isolation strip, so that interference between a digital circuit and an analog circuit can be avoided, the stability of signal transmission is improved, and the overall operation speed of the data acquisition device is improved by processing different signals by different controllers.

As shown in fig. 7, a memory card 140 and a data transmission module 139 are further disposed on the substrate 112, and both the memory card 140 and the data transmission module 139 are connected to the second controller 137.

The memory card 140 is configured to receive and store the physiological data in the form of digital signals transmitted by the second controller 137; and the data transmission module 139 is configured to receive the physiological data in the form of digital signals transmitted by the second controller 137, and upload the received physiological data to other electronic devices, where the transmission mode includes communication modes such as WIFI and bluetooth.

It can be seen that the acquired data can be stored by the memory card 140, so that data loss is prevented, and the data transmission module 139 can upload the acquired physiological data of the patient to other electronic devices in real time, so that medical staff can perform post-processing and analysis on the data of the patient for clinical diagnosis.

In a possible scenario, based on the above-mentioned embodiment, in order to facilitate the caregiver to quickly obtain the information of the patient, referring to fig. 5, the data collecting apparatus further includes a code scanner 124, and the code scanner 124 is fixedly disposed on the top of the second housing 110 and connected to the second controller.

The code scanner 124 is configured to scan a two-dimensional code or a barcode of the patient identity information, and send the obtained user identity information to the second controller 137, where the second controller 137 associates the user identity information with corresponding physiological data in the form of digital signals.

For example, when the code scanner 124 is fixedly disposed on the top of the second housing 110, a through hole may be formed on the top of the second housing 110, and the code scanner 124 is fixedly connected to the second housing 110 by being inserted into the through hole.

It can be seen that the barcode scanner 124 is installed on the top of the second housing 110, which is convenient for the caregiver to operate, can read the information of the patient quickly, and can associate the physiological data detected by the patient with the identity information, thereby ensuring the accuracy of the data record.

Further, in order to mount the code scanner 124 more stably and not easily shake, as shown in fig. 6, in the second housing 110, sixth positioning posts 119 are respectively disposed at two ends of the through hole, for easy understanding, as shown in fig. 3, a fourth pressing piece 128 is disposed at the top of the code scanner 124, the fourth pressing piece 128 is pressed against the top surface of the code scanner 124, and two ends of the fourth pressing piece 128 are fixedly connected to the tops of the two sixth positioning posts 119.

The heights of the two sixth positioning pillars 119 are slightly lower than the height of the code scanner 124.

It can be seen that, under the condition that the heights of the two sixth positioning columns 119 are slightly lower than the height of the code scanner 124, two ends of the fourth pressing piece 128 are connected with the two sixth positioning columns 119, two ends of the fourth pressing piece 128 are lower than the code scanner 124, the middle part of the fourth pressing piece 128 is located on the top surface of the code scanner 124, and under the elastic action of the fourth pressing piece 128 itself, pressure is applied to the top surface of the code scanner 124 to press the code scanner 124, so that the code scanner is more stably installed and is not easy to shake.

In one possible scenario, based on the above embodiment, in order to facilitate the caregiver to view the patient information and the detected physiological data, referring to fig. 5, the data acquisition device further includes a display screen assembly 132, and the display screen assembly 132 is embedded in the outer surface of the first housing 109.

The display screen assembly 132 includes a display screen and a touch screen, both the display screen and the touch screen are connected to the second controller 137, the touch screen is configured to detect a touch signal of a user and send the touch signal to the second controller 137, the second controller 137 determines, based on the received touch signal, target output content matched with the touch signal, and controls the display screen to display the target output content, and the touch screen may be a capacitive touch screen or a resistive touch screen.

It can be seen that through at first casing 109 surface mounting display screen subassembly 132 for the nursing staff can be more convenient look over patient's identity information and the physiological data who detects, and in addition, through the setting of touch-sensitive screen, the nursing staff can directly carry out human-computer interaction through the touch-sensitive screen, carries out work with control data acquisition equipment, and it is more convenient to operate.

Exemplarily, in order to remind the caregiver, as shown in fig. 5, a light guide post 133 is disposed at the bottom of the first housing 109, and the light guide post 133 is used for guiding the light source disposed on the substrate 112 out of the outer surface of the housing 101, so as to serve as an indicator light and beautify the appearance of the housing, and achieve the purpose of reminding the caregiver through the indicator light.

In a possible scenario, based on the above embodiment, in order to assist the nursing staff to monitor the physiological condition of the patient, referring to fig. 5, the data collecting apparatus further includes a speaker 134, and the speaker 134 is fixedly disposed on the second housing 110 and connected to the second controller 137.

Wherein, the speaker 134 is used for outputting prompt information when the second controller 137 detects that the value corresponding to the physiological data is higher than the preset threshold, for example, when the measured value of the physiological data of the patient is higher than the preset value, the speaker 134 emits a sound to prompt.

For example, as shown in fig. 6, when the speaker 134 is installed, two fourth positioning pillars 117 are disposed at positions close to the top of the accommodating space inside the second housing 110, a second accommodating portion 121 is disposed between the two fourth positioning pillars 117, the shape of the second accommodating portion 121 is adapted to the speaker 134, and the speaker 134 is disposed in the second accommodating portion 121.

It can be seen that, when the physiological data of the patient is detected, when the measured value of the physiological data is higher than the preset value, it is indicated that the physiological data of the patient has a problem, the speaker 134 makes a sound to prompt, so that the nursing staff can pay attention to the physiological data of the patient, and the nursing staff can be assisted to monitor the physical condition of the patient.

For example, as shown in fig. 3, in order to make the installation of the speaker 134 more stable and prevent the speaker 134 from shaking, a third pressing piece 127 is disposed on the top of the speaker 134, the third pressing piece 127 is pressed against the top surface of the speaker 134, and two ends of the third pressing piece 127 are fixedly connected to the tops of the two fourth positioning posts 117. The heights of the two fourth positioning posts 117 are slightly lower than the height of the speaker 134.

It can be seen that, under the condition that the heights of the two fourth positioning columns 117 are slightly lower than the height of the speaker 134, two ends of the third pressing piece 127 are connected with the two fourth positioning columns 117, two ends of the third pressing piece 127 are lower than the speaker 134, the middle portion of the third pressing piece 127 is located on the top surface of the speaker 134, and under the elastic action of the third pressing piece 127, the top surface of the speaker 134 is pressed to compress the speaker 134, so that the mounting of the speaker is more stable, and the speaker is not prone to shake.

In a possible scenario, based on the above embodiment, in order to enable the data acquisition device to still perform data transmission under the condition that the wireless network signal is weaker, referring to fig. 8, fig. 8 is an overall structural schematic diagram of another view angle of the data acquisition device, which is provided by the present invention, further comprising a card slot 130 for accommodating the user identification card, wherein the card slot 130 is externally disposed on the second side surface of the second housing 110, and is connected to the second controller 137.

The card slot 130 is configured to provide a mobile network for the data acquisition device through the user identification card when the second controller 137 monitors that the wireless network signal is smaller than the signal threshold.

It can be seen that, through setting up draw-in groove 130, can be when radio signal is more weak, the automatic switch-over is the mobile data mode, uploads data at any time, does not receive place network environment restriction to through external draw-in groove 130, make user identification card can change user identification card at any time according to the difference of in service behavior, in order to adapt to different network environment.

In a possible scenario, based on the above embodiment, in order to enable the data acquisition device to be suitable for more application scenarios, referring to fig. 8, the data acquisition device further includes a universal serial bus interface 131, and the universal serial bus interface 131 is externally disposed on the second side of the second housing 110 and is connected to the second controller 137.

The usb interface 131 is configured to be connected to an external power supply device, so as to supply power to the data acquisition device through the external power supply device, and send a power supply signal to the second controller 137, where the second controller 137 displays a power-on state based on the power supply signal.

Alternatively, the usb interface 131 is used to connect with other expansion devices to receive control signals of the other expansion devices and send the control signals to the second controller 137, and the second controller 137 responds based on the control signals.

Or, the usb interface 131 is used to connect with other electronic devices to transmit the acquired physiological data to other electronic devices, and the second controller 137 communicates with other electronic devices through the usb interface 131 to transmit the acquired physiological data in the form of digital signals to other electronic devices through the usb interface 131.

Or, the usb interface 131 is configured to connect with other detection devices to obtain parameter data of the other detection devices, and send the parameter data of the other detection devices to the second controller 137, and the second controller 137 transmits the parameter data to the first controller 136, so that the first controller 136 updates parameters of the detection program.

Or, the usb interface 131 is used to connect with other control devices to perform system upgrade operations under the control of other control devices, and the second controller 137 communicates with other control devices through the usb interface 131, receives system upgrade data of other control devices, and upgrades the system based on the system upgrade data.

It can be seen that, by providing the usb interface 131 on the second side of the second housing 110, the second housing can be connected to an external power supply device to supply power to the data acquisition device; the external expansion equipment can be connected, and the data acquisition equipment is convenient to operate; the acquired data can be transmitted to other electronic equipment, so that the data sharing is facilitated; the parameter updating can be carried out on the program for collecting the physiological data; the accuracy of data acquisition is improved; the system can be upgraded to meet the requirement and requirement of continuous updating; therefore, the capacity of adapting to more different application scenes of the data acquisition equipment is improved, in addition, the universal serial bus interface 131 is arranged on the second side face of the second shell 110, the data acquisition equipment can also be conveniently connected with external equipment, and the wire connected with the acquisition interface and the external monitoring equipment is prevented from colliding.

In a possible scenario, based on the above embodiment, in order to facilitate the caregiver to perform the on/off operation on the data acquisition device, referring to fig. 8, the data acquisition device further includes an on/off button 129, and the on/off button 129 is installed on the second side surface of the second housing 110 and connected to the second controller 137.

The power on/off key 129 is configured to receive a pressing operation of a user on the power on/off key 129, and send a received signal of the pressing operation to the second controller 137, where the second controller 137 executes a corresponding power on operation or power off operation when receiving the signal of the pressing operation.

For example, when the power on/off button 129 is provided, the power on/off button 129 may be installed on the second side of the second housing 110 near the bottom third of the second housing for the caregiver to perform the power on/off operation.

It can be seen that, by setting the power on/off key 129, the nursing staff can perform power on/off operation on the data acquisition device through simple pressing operation, so as to facilitate the nursing staff to operate the data acquisition device, and in addition, by installing the power on/off key 129 at the second side of the second shell 110, the power on/off key 129 is located at a position close to one third of the bottom, so as to facilitate the nursing staff to operate the power on/off key 129 with one hand when the operation with two hands is inconvenient.

In a possible scenario, based on the above embodiment, in order to enable the data acquisition device to be normally used under the condition of no power supply, referring to fig. 5, the data acquisition device further includes a battery 135, and the battery 135 is fixedly disposed in the lower area of the accommodating space inside the second housing 110 and is connected to the first controller 136 and the second controller 137.

The battery 135 is used for supplying power to the first controller 136 and the second controller 137.

For example, as shown in fig. 6, when the battery 135 is installed, two sets of the fourth baffle 122 and the fifth baffle 123 perpendicular to each other may be disposed in the inner space surrounded by the four first positioning posts 114, the two sets of the fourth baffle 122 and the fifth baffle 123 form a receiving groove, and the battery 135 is disposed in the receiving groove.

For example, when two sets of the fourth baffle and the fifth baffle 123 are disposed perpendicular to each other, the fourth baffle 122 and the fifth baffle 123 may be disposed at edge positions of the inner space formed by the four first positioning pillars 114, respectively, and both the fourth baffle 122 and the fifth baffle 123 are fixedly connected to the second housing 110 and perpendicular to the second housing 110; the volume of the accommodating groove formed by the battery cell can be maximized, and a large enough battery 135 can be placed into the accommodating groove, so that the cruising ability of the data acquisition equipment is improved.

For example, in order to more stably fix the battery 135 in the receiving groove, an adhesion structure may be provided at a position where the battery 135 contacts the second housing 110 when the battery 135 is disposed in the receiving groove.

For example, the battery 135 may be a rechargeable battery structure, or a replaceable battery structure, and when the battery 135 is a rechargeable battery structure, the battery 135 can be charged through the usb interface 131 in the above embodiments; when the battery 135 has a replaceable battery structure, a replacement cover is provided at a position of the second housing 110 corresponding to the battery 135.

It can be seen that through setting up battery 135 for data acquisition equipment also can normally work under the condition that does not have the power supply condition, for example when having a power failure, or outdoor region, thereby make data acquisition equipment have stronger adaptability, in addition, through setting up battery 135 in the below region of the inside accommodation space of second casing 110, can make overall structure overall arrangement more reasonable, the focus is more steady, the light phenomenon of head and foot can not appear.

In a possible scenario, based on the above embodiment, in order to enable the data acquisition device to acquire non-main physiological data required by the nursing staff, the data acquisition device further includes an external parameter collector, the external parameter collector is connected to the non-main physiological data external monitoring device, and the external parameter collector is connected to the second controller 137. Illustratively, the non-primary physiological data may include body temperature, blood sugar, lung function, etc., and may be specifically set according to actual needs.

The external parameter collector is mainly used for collecting non-main physiological data collected by non-main physiological parameter external monitoring equipment connected with the external parameter collector, and transmitting the received non-main physiological data to the second controller 137.

Therefore, the data acquisition equipment can acquire non-main physiological data required by nursing staff by configuring the external parameter acquisition device, so that more detection requirements can be met.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A data acquisition device is characterized by comprising a shell with an accommodating space, a first controller, a pump valve assembly, a blood pressure data acquisition interface and other physiological data acquisition interfaces, wherein the first controller, the pump valve assembly, the blood pressure data acquisition interface and the other physiological data acquisition interfaces are arranged in the shell, the other physiological data acquisition interfaces are fixedly arranged on the shell, the other physiological data acquisition interfaces are connected with the first controller, and the blood pressure data acquisition interface is connected with the first controller through the pump valve assembly;

the pump valve assembly comprises an air pump, an air valve and a pipeline for connecting the air pump and the air valve, and the air valve is fixedly arranged in the accommodating space and close to the blood pressure data acquisition interface and is connected with the blood pressure data acquisition interface; the air pump is fixedly arranged at one side of the air valve far away from the blood pressure data acquisition interface through a first baffle, a second baffle and a third baffle;

the first baffle is tightly attached to the middle position of one side, away from the longitudinal section, of the air pump transverse section, the second baffle and the third baffle are respectively tightly attached to the left side and the right side of the air pump longitudinal section, and the end faces, close to one side of the air pump transverse section, of the second baffle and the third baffle are abutted to the air pump transverse section.

2. The data acquisition device of claim 1, wherein the housing comprises a first housing and a second housing disposed below the first housing, and the blood pressure data acquisition interface and the other physiological data acquisition interfaces are both fixedly disposed on a first side of the second housing;

wherein, the other physiological data acquisition interfaces comprise an acquisition interface corresponding to blood oxygen data and/or an acquisition interface corresponding to pulse rate data.

3. The data acquisition device as claimed in claim 2, wherein the first controller is disposed on a substrate, the substrate is fixedly disposed on the second housing, and a second controller is disposed on the substrate and spaced from the first controller.

4. The data acquisition device according to claim 3, further comprising a code scanner fixedly disposed at the top end of the second housing and connected to the second controller;

the code scanner is used for scanning a two-dimensional code or a bar code of the user identity information and sending the obtained user identity information to the second controller.

5. The data acquisition device of claim 3, further comprising a display screen assembly embedded in the outer surface of the first housing, the display screen assembly comprising a display screen and a touch screen, both the display screen and the touch screen being connected to the second controller;

the touch screen is used for detecting a touch signal of a user and sending the touch signal to the second controller.

6. The data acquisition device of claim 3, further comprising a speaker fixedly disposed on the second housing and connected to the second controller;

the loudspeaker is used for outputting prompt information.

7. The data acquisition device as claimed in claim 3, further comprising a card slot for accommodating a user identification card, wherein the card slot is externally arranged on the second side surface of the second housing and connected with the second controller;

the card slot is used for providing a mobile network for the data acquisition equipment through the user identification card.

8. The data acquisition device according to claim 3, further comprising a universal serial bus interface externally disposed on the second side of the second housing and connected to the second controller;

the universal serial bus interface is used for being connected with external power supply equipment to supply power to the data acquisition equipment through the external power supply equipment, or used for being connected with external expansion equipment to receive a control signal of the external expansion equipment, or used for being connected with other electronic equipment to transmit acquired physiological data to the other electronic equipment.

9. The data acquisition device as claimed in claim 3, further comprising a power on/off button fixedly disposed on the second side of the second housing and connected to the second controller;

the power on/off key is used for receiving pressing operation of a user on the power on/off key.

10. The data acquisition device according to any one of claims 3 to 9, further comprising a battery fixedly disposed in a lower region of the accommodating space and connected to the first controller and the second controller;

the battery is used for supplying power to the first controller and the second controller.

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