CN219354527U - Synchronous multi-position display and physical sign monitoring bed system based on gastrointestinal endoscopy - Google Patents

Abstract

The utility model discloses a synchronous multi-position display and sign monitoring bed system based on gastrointestinal endoscopy, which comprises: the bed body structure comprises a bearing bed plate and two groups of guide sliding rails which are fixedly connected and assembled on two sides of the bearing bed plate in a one-to-one correspondence manner, and each group of guide sliding rails is provided with a positioning sliding block in a sliding manner; the heart rate monitoring assembly is fixedly arranged at the top end of the positioning sliding block of one group of guide sliding rails; the respiration rate monitoring assembly is fixedly arranged at the top end of the positioning sliding block of the other group of guide sliding rails; the synchronous display assembly is movably assembled at one side part of the bearing bed board in an adjustable position; the control input end of the control assembly is connected with the heart rate monitoring assembly and the respiratory rate monitoring assembly through circuits respectively, and the control output end of the control assembly is connected with the synchronous display assembly through circuits. Solves the technical problems that the bed body used for carrying out the endoscopy in the prior art has single functionality, is difficult to finish monitoring other physical signs except the endoscopy and can not synchronously observe.

Description

Synchronous multi-position display and physical sign monitoring bed system based on gastrointestinal endoscopy

Technical Field

The utility model relates to the technical field of auxiliary instruments for endoscopy, in particular to a synchronous multi-position display and physical sign monitoring bed system based on gastrointestinal endoscopy.

Background

Currently, a gastrointestinal endoscope is a medical examination instrument for performing a searchlight examination of a lesion inside the gastrointestinal tract, and when performing the endoscopy, a patient needs to maintain a specific posture in a bed for a long time to complete the examination operation. However, because the traditional bed body that is used for lying is conventional function bed body, whole functional comparatively singleness, consequently when long-time inspection operation, the patient can only cooperate medical personnel to accomplish the endoscopic examination operation of requirement completion, is difficult to accomplish other types of sign monitoring, is difficult to observe simultaneously from physical sign situation and endoscopic examination condition.

Disclosure of Invention

Therefore, the utility model provides a synchronous multi-position display and sign monitoring bed system based on gastrointestinal endoscopy, which aims to solve the technical problems that the functionality of a bed body used for performing the endoscopy is single, and other sign monitoring except for the endoscopy is difficult to complete and synchronous observation cannot be performed in the prior art.

In order to achieve the above object, the present utility model provides the following technical solutions:

a synchronized multi-position display and sign monitoring bed system based on gastrointestinal microscopy, comprising:

the bed body structure comprises a bearing bed plate and two groups of guide sliding rails which are fixedly assembled on two sides of the bearing bed plate in a one-to-one correspondence manner, and each group of guide sliding rails is provided with a position adjusting sliding block in a sliding manner;

the heart rate monitoring assembly is fixedly arranged at the top end of the positioning sliding block of one group of the guiding sliding rails;

the respiration rate monitoring assembly is fixedly arranged at the top end of the position-adjusting sliding block of the other group of guide sliding rails;

the synchronous display assembly is movably assembled at one side part of the bearing bed board in an adjustable position;

the control input end of the control assembly is respectively connected with the heart rate monitoring assembly and the respiratory rate monitoring assembly through a circuit, and the control output end of the control assembly is connected with the synchronous display assembly through a circuit.

On the basis of the technical scheme, the utility model is further described as follows:

as a further scheme of the utility model, the bed body structure further comprises a bottom supporting frame.

The bottom support frames are vertically provided with a plurality of groups, and the bearing bed board is fixedly assembled at the top ends of the plurality of groups of bottom support frames; and each group of guide sliding rails is slidably provided with a plurality of position-adjusting sliding blocks.

As a further aspect of the present utility model, the heart rate monitoring assembly includes a first vertical telescopic rod, a first horizontal telescopic rod, and a heart rate monitoring sensor.

The bottom rigid coupling of first vertical telescopic link is assembled in one of them a set of direction slide rail the slider of positioning, just the top of first vertical telescopic link with drive the rigid coupling between the one end of first horizontal telescopic link links to each other, just first vertical telescopic link with set up perpendicularly between the first horizontal telescopic link, the other end of first horizontal telescopic link with the rigid coupling links to each other between the heart rate monitoring sensor.

As a further aspect of the present utility model, the respiration rate monitoring assembly includes a second vertical telescopic rod, a second horizontal telescopic rod, and a respiration rate monitoring sensor.

The bottom rigid coupling of second vertical telescopic link assemble in another group one of the direction slide rail the position adjustment slider, just the top of second vertical telescopic link with drive the rigid coupling between the one end of second horizontal telescopic link links to each other, the second vertical telescopic link with mutually perpendicular setting between the second horizontal telescopic link, the other end of second horizontal telescopic link with the rigid coupling links to each other between the respiration rate monitoring sensor.

As a further aspect of the present utility model, the respiratory rate monitoring assembly further comprises an adaptive pressure transmitting balloon.

The self-adaptive pressure transmission air bag is fixedly connected to the front face of the respiration rate monitoring sensor.

As a further aspect of the present utility model, the synchronous display assembly includes a mount, a first actuator arm, a second actuator arm, and a display.

The mounting seat is fixedly connected to one side part of the bearing bed board, which corresponds to the middle of the two groups of guide sliding rails; one end of the first transmission arm is assembled on the top end face of the mounting seat in a switching mode, one end of the second transmission arm is connected with the other end of the first transmission arm in a switching mode, planes of the first transmission arm and the second transmission arm in the rotating direction are perpendicular to the guide sliding rail, and the other end of the second transmission arm is connected with one side portion of the display in a switching mode.

As a further aspect of the present utility model, the synchronous display assembly further includes a bullseye bearing.

The other end of the second transmission arm is connected with one side part of the display through universal switching.

As a further scheme of the utility model, a finger clip oximeter is further arranged at one side of the bearing bed board, and the finger clip oximeter is electrically connected with the control input end of the control component through an blood oxygen wiring.

As a further scheme of the utility model, one side part of the bearing bed board is also provided with an electrocardiograph contact, and the electrocardiograph contact is electrically connected with the control input end of the control assembly through an electrocardiograph wiring.

As a further scheme of the utility model, the control assembly comprises an electric control module and a control panel electrically connected with a control input end of the electric control module; the electric control module comprises a mobile power supply and a control module which are connected through a circuit.

The control input end of the control module is respectively connected with the heart rate monitoring assembly, the respiratory rate monitoring assembly, the finger clip oximeter and the electrocardiograph contact through a circuit, and the control output end of the control module is connected with the synchronous display assembly through a circuit.

The utility model has the following beneficial effects:

the system can synchronously monitor the heart rate and respiratory rate sign data of a lying human body during endoscopy by utilizing the heart rate monitoring assembly and the respiratory rate monitoring assembly through the bed body structure on the basis of completing a set auxiliary lying function, and can synchronously display sign conditions and endoscopic examination conditions by a patient or other medical staff conveniently by means of the synchronous display assembly, so that examination efficiency and accuracy are further improved, patient safety is guaranteed, and functional practicability of the whole system is further effectively improved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the following description will simply refer to the drawings required in the embodiments or the description of the prior art, and structures, proportions, sizes and the like which are shown in the specification are merely used in conjunction with the disclosure of the present utility model, so that those skilled in the art can understand and read the disclosure, and any structural modifications, changes in proportion or adjustment of sizes should still fall within the scope of the disclosure of the present utility model without affecting the effects and the achieved objects of the present utility model.

FIG. 1 is a schematic diagram of an overall axial structure of a gastrointestinal endoscopy-based synchronous multi-position display and physical sign monitoring bed system according to an embodiment of the present utility model.

FIG. 2 is a schematic diagram of a second embodiment of a gastrointestinal microscopy-based synchronized multi-position display and physical sign monitoring couch system overall axially.

In the drawings, the list of components represented by the various numbers is as follows:

bed body structure 1: the bottom support frame 11, the bearing bed board 12, the guide slide rail 13 and the positioning slide block 14;

heart rate monitoring assembly 2: a first vertical telescopic rod 21, a first horizontal telescopic rod 22 and a heart rate monitoring sensor 23;

respiration rate monitoring component 3: the second vertical telescopic rod 31, the second horizontal telescopic rod 32, the respiratory rate monitoring sensor 33 and the self-adaptive pressure transmitting air bag 34;

synchronous display assembly 4: mounting base 41, first drive arm 42, second drive arm 43, bullseye bearing 44, display 45;

finger clip oximeter 5, blood oxygen wiring 51;

electrocardiograph contact 6, electrocardiograph connection 61.

Detailed Description

Other advantages and advantages of the present utility model will become apparent to those skilled in the art from the following detailed description, which, by way of illustration, is to be read in connection with certain specific embodiments, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The terms such as "upper", "lower", "left", "right", "middle" and the like are also used herein for descriptive purposes only and are not intended to limit the scope of the utility model for which the utility model may be practiced or for which the relative relationship may be altered or modified without materially altering the technical context.

As shown in fig. 1 to 2, the embodiment of the utility model provides a synchronous multi-position display and sign monitoring bed system based on gastrointestinal endoscopy, which comprises a bed body structure 1, a heart rate monitoring component 2, a respiratory rate monitoring component 3 and a synchronous display component 4, wherein the synchronous display component 4 is used for synchronously monitoring heart rate and respiratory rate sign data of a lying human body in endoscopy by using the heart rate monitoring component 2 and the respiratory rate monitoring component 3 on the basis of completing a set auxiliary lying function through the bed body structure 1, and conveniently synchronously displaying sign conditions and endoscopic examination conditions by a patient or other medical staff by means of the synchronous display component 4, so that the examination efficiency and accuracy are further improved, the patient safety is ensured, and the functional practicability is further improved. The specific arrangement is as follows:

referring to fig. 1 to 2, the bed structure 1 includes a bottom support frame 11, a bearing bed board 12, a guide sliding rail 13 and a positioning sliding block 14; wherein, the bottom support frame 11 is vertically provided with a plurality of groups, the bearing bed board 12 is fixedly assembled at the top ends of the plurality of groups of bottom support frames 11, so as to complete the given auxiliary lying function and serve as a support foundation of the whole framework; the guide slide rails 13 are provided with two groups, the two groups of guide slide rails 13 are fixedly connected and assembled on two side parts of the bearing bed board 12 in a one-to-one correspondence manner respectively, and each group of guide slide rails 13 is slidably provided with a plurality of positioning slide blocks 14; the heart rate monitoring assembly 2 is fixedly connected and assembled on one of the positioning slide blocks 14 of one group of the guiding slide rails 13, the respiration rate monitoring assembly 3 is fixedly connected and assembled on the other group of one of the positioning slide blocks 14 of the guiding slide rails 13, so that the heart rate monitoring assembly 2 and the respiration rate monitoring assembly 3 can flexibly slide and adjust positions according to people of different sizes respectively, the heart rate monitoring assembly 2 can effectively correspond to the heart part of the back of a human body, the respiration rate monitoring assembly 3 can effectively correspond to the upper abdomen part of the front of the human body, real-time monitoring of the heart rate and the respiration rate of the human body is further completed, and the functional flexibility of the structure is effectively improved.

Specifically, the heart rate monitoring assembly 2 comprises a first vertical telescopic rod 21, a first horizontal telescopic rod 22 and a heart rate monitoring sensor 23; the bottom end of the first vertical telescopic rod 21 is fixedly connected and assembled to one of the guide sliding rails 13, one of the guide sliding blocks 14 is connected with the top end of the first vertical telescopic rod 21 and one end of the first transverse telescopic rod 22 in a transmission and fixedly connection mode, the first vertical telescopic rod 21 and the first transverse telescopic rod 22 are vertically arranged, the other end of the first transverse telescopic rod 22 is fixedly connected with the back side surface of the heart rate monitoring sensor 23 in a fixedly connection mode, and the vertical height of the heart rate monitoring sensor 23 and the inward extension length of the heart rate monitoring sensor 23 are further adjusted through the first vertical telescopic rod 21 and the first transverse telescopic rod 22, so that the front face of the heart rate monitoring sensor 23 can be stably contacted with the heart part of the back of a human body, and the heart rate monitoring function is further achieved.

The respiratory rate monitoring assembly 3 comprises a second vertical telescopic rod 31, a second horizontal telescopic rod 32, a respiratory rate monitoring sensor 33 and an adaptive pressure transmission air bag 34; the bottom end of the second vertical telescopic rod 31 is fixedly connected and assembled to one of the positioning sliding blocks 14 of the other group of guiding sliding rails 13, the top end of the second vertical telescopic rod 31 is fixedly connected with one end of the second horizontal telescopic rod 32 in a transmission manner, the second vertical telescopic rod 31 and the second horizontal telescopic rod 32 are vertically arranged, the other end of the second horizontal telescopic rod 32 is fixedly connected with the back side surface of the respiration rate monitoring sensor 33 in a fixedly connected manner, the self-adaptive air-transmitting bag 34 is fixedly connected to the front surface of the respiration rate monitoring sensor 33, the vertical height of the respiration rate monitoring sensor 33 and the inward extension length of the respiration rate monitoring sensor 33 are further adjusted through the second vertical telescopic rod 31 and the second horizontal telescopic rod 32, so that the self-adaptive air-transmitting bag 34 can be stably pressed on the upper abdomen position of the front side of a human body, and the amplitude change of the upper abdomen respiration can be effectively transmitted to the respiration rate monitoring sensor 33 through the self-adaptive air-transmitting bag 34 on the basis of ensuring normal respiration of the human body, and the monitoring function of the respiration rate is further realized.

With continued reference to fig. 1-2, the synchronous display assembly 4 includes a mounting base 41, a first driving arm 42, a second driving arm 43, a bullseye bearing 44, and a display 45; wherein, the mounting seat 41 is fixedly connected to one side part of the bearing bed board 12 corresponding to the middle of the two groups of the guide slide rails 13; one end of the first driving arm 42 is assembled on the top end surface of the mounting seat 41 in a switching manner, one end of the second driving arm 43 is connected with the other end of the first driving arm 42 in a switching manner, planes of the first driving arm 42 and the second driving arm 43 in the rotating direction are perpendicular to the guiding sliding rail 13, and the other end of the second driving arm 43 is connected with one side of the display 45 in a universal switching manner through the bullseye bearing 44; the device is used for synchronously displaying physical sign conditions and endoscopic examination conditions by means of the display 45, and meanwhile the display 45 can be flexibly adjusted in height, distance and angle based on the head position of a human body through the structure, so that the functional convenience and practicality are remarkably improved.

As a preferred solution of this embodiment, a finger-clip oximeter 5 is further disposed at a side portion of the support bed board 12 corresponding to the front surface of the human body, and the finger-clip oximeter 5 is electrically connected to the built-in control component through an oxygen connection 51, so as to use the finger-clip oximeter 5 to realize real-time effective monitoring of the oxygen content of the human body.

As another preferred solution of this embodiment, an electrocardiograph contact 6 is further disposed on a side portion of the support bed board 12 corresponding to the front face of the human body, and the electrocardiograph contact 6 is electrically connected to the built-in control component through an electrocardiograph connection 61, so that real-time effective monitoring of the electrocardiograph condition of the human body is achieved by using the electrocardiograph contact 6, and thus monitoring of other signs except for endoscopic examination can be further performed, and patient monitoring dimensions are improved.

It should be noted that the control assembly includes an electrically connected electronic control module and a control panel; the electronic control module comprises a mobile power supply and a control module which are connected through a circuit, wherein the mobile power supply can adopt but not limited to a lithium battery, and the control module can select but not limited to a singlechip control board with the model of AT80C51 and a microcontroller with the model of STM 32; the control input end of the control module is respectively connected with the heart rate monitoring sensor 23, the respiration rate monitoring sensor 33, the finger clip oximeter 5 and the electrocardiograph contact 6 through a circuit, and the control output end of the control module is connected with the display 45 through a circuit, so that the normal and stable operation of the system function is ensured, and the degree of automation is improved.

While the utility model has been described in detail in the foregoing general description and specific examples, it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, such modifications or improvements may be made without departing from the spirit of the utility model and are intended to be within the scope of the utility model as claimed.

Claims (10)

1. A synchronized multi-position display and sign monitoring bed system based on gastrointestinal microscopy, comprising:

the bed body structure comprises a bearing bed plate and two groups of guide sliding rails which are fixedly assembled on two sides of the bearing bed plate in a one-to-one correspondence manner, and each group of guide sliding rails is provided with a position adjusting sliding block in a sliding manner;

the heart rate monitoring assembly is fixedly arranged at the top end of the positioning sliding block of one group of the guiding sliding rails;

the respiration rate monitoring assembly is fixedly arranged at the top end of the position-adjusting sliding block of the other group of guide sliding rails;

the synchronous display assembly is movably assembled at one side part of the bearing bed board in an adjustable position;

the control input end of the control assembly is respectively connected with the heart rate monitoring assembly and the respiratory rate monitoring assembly through a circuit, and the control output end of the control assembly is connected with the synchronous display assembly through a circuit.

2. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 1,

the bed body structure also comprises a bottom supporting frame;

the bottom support frames are vertically provided with a plurality of groups, and the bearing bed board is fixedly assembled at the top ends of the plurality of groups of bottom support frames; and each group of guide sliding rails is slidably provided with a plurality of position-adjusting sliding blocks.

3. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 2, wherein,

the heart rate monitoring assembly comprises a first vertical telescopic rod, a first horizontal telescopic rod and a heart rate monitoring sensor;

the bottom rigid coupling of first vertical telescopic link is assembled in one of them a set of direction slide rail the slider of positioning, just the top of first vertical telescopic link with drive the rigid coupling between the one end of first horizontal telescopic link links to each other, just first vertical telescopic link with set up perpendicularly between the first horizontal telescopic link, the other end of first horizontal telescopic link with the rigid coupling links to each other between the heart rate monitoring sensor.

4. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 2, wherein,

the respiration rate monitoring assembly comprises a second vertical telescopic rod, a second horizontal telescopic rod and a respiration rate monitoring sensor;

the bottom rigid coupling of second vertical telescopic link assemble in another group one of the direction slide rail the position adjustment slider, just the top of second vertical telescopic link with drive the rigid coupling between the one end of second horizontal telescopic link links to each other, the second vertical telescopic link with mutually perpendicular setting between the second horizontal telescopic link, the other end of second horizontal telescopic link with the rigid coupling links to each other between the respiration rate monitoring sensor.

5. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 4,

the respiratory rate monitoring assembly further comprises an adaptive pressure transmitting air bag;

the self-adaptive pressure transmission air bag is fixedly connected to the front face of the respiration rate monitoring sensor.

6. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 1,

the synchronous display assembly comprises a mounting seat, a first transmission arm, a second transmission arm and a display;

the mounting seat is fixedly connected to one side part of the bearing bed board, which corresponds to the middle of the two groups of guide sliding rails; one end of the first transmission arm is assembled on the top end face of the mounting seat in a switching mode, one end of the second transmission arm is connected with the other end of the first transmission arm in a switching mode, planes of the first transmission arm and the second transmission arm in the rotating direction are perpendicular to the guide sliding rail, and the other end of the second transmission arm is connected with one side portion of the display in a switching mode.

7. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 6,

the synchronous display assembly further comprises a bullseye bearing;

the other end of the second transmission arm is connected with one side part of the display through universal switching.

8. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 1,

and a finger-clamping oximeter is further arranged at one side of the bearing bed board and is electrically connected with the control input end of the control assembly through an blood oxygen wiring.

9. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 8,

an electrocardiograph contact is further arranged on one side of the bearing bed plate and is electrically connected to the control input end of the control assembly through an electrocardiograph wiring.

10. The gastrointestinal microscopy-based simultaneous multi-position display and sign monitoring bed system of claim 9,

the control assembly comprises an electric control module and a control panel electrically connected with a control input end of the electric control module; the electric control module comprises a mobile power supply and a control module which are connected through a circuit;

the control input end of the control module is respectively connected with the heart rate monitoring assembly, the respiratory rate monitoring assembly, the finger clip oximeter and the electrocardiograph contact through a circuit, and the control output end of the control module is connected with the synchronous display assembly through a circuit.