CN217612305U - Small-size real-time speed display that drips - Google Patents

Abstract

The utility model discloses a small real-time dripping speed display, the components of which are arranged inside an outer protective shell and a side inner protective shell, the side inner protective shell is embedded inside the side surface of the outer protective shell; the method comprises the following steps: the built-in computing chip is fixedly installed inside the outer protective shell in an embedded mode, and a display screen is fixedly embedded on one side of the upper surface of the outer protective shell in an embedded mode; the outer limiting groove penetrates through the inner part of the outer protective shell; the connector is fixedly arranged on the upper surface of the side inner protective shell, and one side of the connector is embedded and correspondingly arranged on the side surface of the outer protective shell; the inner limiting groove penetrates through the inner portion of the side inner protective shell, and an infrared inductor is mounted on the side face of the inner limiting groove. This small-size real-time fast display that drips adopts neotype structural design for this device can quick block install in the outside of Murphy's burette, drips fast through the infrared induction structure in real time to the infusion and detects, and it is comparatively convenient to use.

Description

Small-size real-time dripping speed display

Technical Field

The utility model relates to a clinical care technical field specifically is a small-size real-time speed display that drips.

Background

In the clinical nursing work, the regulation of the liquid dropping speed through an infusion apparatus or a blood transfusion apparatus is one of the most common actions, except for medicine infusion, TPN (thermoplastic vulcanizate) infusion, abdominal cavity irrigation, bladder irrigation and the like also need to regulate the dropping speed frequently, when the medicine is infused, the dropping speed of the medicine needs to be regulated according to different medicines and specific conditions of patients, for example, the patient with heart failure needs to control the infusion amount per hour, the dropping speed needs to be regulated not too fast, generally, the regulation can be carried out by using auxiliary equipment such as a watch and the like, or the regulation can be directly carried out according to eye observation and clinical experience, when specific medical orders exist, for example, the rate is controlled by 80ml/h, the accurate infusion can be carried out by using equipment such as an infusion pump, and at present, the clinical infusion can also be carried out by using novel devices such as a rate control infusion apparatus.

However, the infusion operation is controlled by devices such as an infusion pump, the real-time infusion speed cannot be observed visually, the infusion cost is controlled by some speed control devices, certain errors also exist when the liquid is controlled to be conveyed in a hose for a long distance, and the observation of the dropping speed is not obvious.

It is therefore desirable to design a small real-time drop rate display that addresses the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a small-size real-time fast display that drips to it is inconvenient to provide but through equipment control infusion operations such as transfer pump in solving above-mentioned background art, and can not comparatively audio-visually observe real-time infusion speed, and it is higher through some quick equipment control infusion costs of accuse, and control liquid also has certain error when long distance transport in the hose, observes the obscure problem of dripping speed.

In order to achieve the above object, the utility model provides a following technical scheme: a small real-time dripping speed display comprises components arranged inside an outer protective shell and a side inner protective shell, wherein the side inner protective shell is embedded inside the side surface of the outer protective shell;

a miniature real-time drop rate display comprising:

the built-in computing chip is fixedly embedded in the outer protective shell, a display screen is fixedly embedded on one side of the upper surface of the outer protective shell, and a battery panel is embedded on one side of the lower surface of the outer protective shell;

the outer limiting groove penetrates through the inner part of the outer protective shell, and the upper surface of the outer protective shell is provided with a linear sliding groove;

the connector is fixedly arranged on the upper surface of the side inner protective shell, one side of the connector is embedded and correspondingly arranged on the side surface of the outer protective shell, and the side surface of the connector is electrically connected with a connecting cable;

the inner limiting groove penetrates through the inner portion of the side inner protective shell, and an infrared inductor is mounted on the side face of the inner limiting groove.

Preferably, the built-in circuit protection block is embedded and fixed in the outer protection shell, limiting columns are symmetrically fixed at two ends of the side face of the built-in circuit protection block, adjusting rods are connected in the side faces of the limiting columns, the adjusting rods are connected with the limiting columns through adjusting springs, and the adjusting rods and the limiting columns are connected with each other through the adjusting springs.

Preferably, the protecting crust constitutes gomphosis extending structure with outer protecting crust in the avris, just the protecting crust constitutes sharp sliding structure with outer protecting crust through sharp slider and sharp spout in the avris, the gomphosis of sharp slider is installed in the inside of sharp spout, according to the pipe diameter size of the Murphy's formula burette, the protecting crust corresponds with outer protecting crust and moves in the control avris, adjusts the size in centre gripping space.

Preferably, the inner limiting groove and the outer limiting groove are communicated and correspond to each other, the inner side surfaces of the inner limiting groove and the outer limiting groove are in arc-shaped structures, and the clamping and limiting of the Murphy dropper can be controlled through the communicated arc-shaped structures.

Preferably, the infrared sensor is arranged on an inner side arc surface of the inner limiting groove, the inner side and the outer side of the infrared sensor are both in arc-shaped structures, and the infusion speed per hour can be conveniently detected in real time according to the speed of the infrared sensor sensing the liquid dropping in the Murphy's dropper.

Preferably, adjust the pole and pass through regulating spring and spacing post constitution elastic telescopic structure, just adjust the side position of pole fixed mounting protecting crust in the avris, can inject the removal adjusting position of protecting crust in the avris through elastic telescopic structure.

Compared with the prior art, the beneficial effects of the utility model are that: this small-size real-time dripping speed display adopts neotype structural design for this device can be convenient sense the real-time dripping speed of infusion through infrared induction structure, is provided with the structure of injecing of murphy's formula burette centre gripping in the device simultaneously, and the installation simple operation, its concrete content is as follows:

1. the small real-time dripping speed display is provided with a sensing real-time dripping speed measuring structure, the device is clamped and arranged outside a Murphy's dropper, an infrared sensor is clamped and arranged outside the Murphy's dropper, according to the condition of the dripping speed of infusion inside the Murphy's dropper, under the sensing condition of measurement of the infrared sensor, the dripping speed measured by the infrared sensor is calculated through a built-in calculating chip, and finally the dripping speed data output is controlled through a display screen, so that medical staff can directly observe the real-time dripping speed of infusion;

2. this small-size real-time dropping speed display is provided with quick block and restricts the structure, and according to the outside diameter size of Murphy's burette, the removal that slides each other between interior protecting crust of control avris and the outer protecting crust, the local position is crisscross each other between outer spacing groove and the interior spacing groove this moment, and outer spacing groove and interior spacing groove block set up in the outside of Murphy's burette, control the quick block installation of the device under the elastic thrust effect of regulating spring, improve the effect that the device installation was used.

Drawings

Fig. 1 is a schematic top view of the present invention;

fig. 2 is a schematic view of the bottom view structure of the present invention;

FIG. 3 is a schematic top view of the present invention in partial cross-sectional view;

fig. 4 is a schematic top view of the adjusting spring of the present invention;

fig. 5 is a schematic view of the vertical surface structure of the inner protective shell of the side of the present invention.

In the figure: 1. an outer protective shell; 2. a computing chip is arranged inside; 3. a display screen; 4. a battery plate; 5. an outer limiting groove; 6. a linear chute; 7. a side inner protective shell; 8. a connector; 9. connecting a cable; 10. an inner limiting groove; 11. an infrared sensor; 12. a linear slider; 13. a circuit protection block is arranged inside; 14. a limiting post; 15. adjusting a rod; 16. the spring is adjusted.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a small real-time dripping speed display comprises components of a dripping speed display which are arranged inside an outer protective shell 1 and an inner protective shell 7 on the side, wherein the inner protective shell 7 on the side is embedded inside the side of the outer protective shell 1;

a miniature real-time drop rate display comprising:

the built-in computing chip 2 is fixedly installed inside the outer protective shell 1 in an embedded mode, a display screen 3 is fixedly embedded in one side of the upper surface of the outer protective shell 1, and a battery panel 4 is installed in one side of the lower surface of the outer protective shell 1 in an embedded mode;

the outer limiting groove 5 penetrates through the inner part of the outer protective shell 1, and the upper surface of the outer protective shell 1 is provided with a linear sliding groove 6;

the connector 8 is fixedly arranged on the upper surface of the side inner protective shell 7, one side of the connector 8 is embedded and correspondingly arranged on the side surface of the outer protective shell 1, and the side surface of the connector 8 is electrically connected with a connecting cable 9;

and the inner limiting groove 10 penetrates through the inner side of the side inner protective shell 7, and an infrared inductor 11 is installed on the side surface of the inner limiting groove 10.

In this example, a built-in circuit protection block 13 is embedded and fixed in the outer protection shell 1, limiting columns 14 are symmetrically fixed at two ends of the side surface of the built-in circuit protection block 13, an adjusting rod 15 is connected in the side surface of the limiting column 14, and the adjusting rod 15 and the limiting column 14 are connected with each other through an adjusting spring 16; the side inner protective shell 7 and the outer protective shell 1 form an embedded telescopic structure, the side inner protective shell 7 and the outer protective shell 1 form a linear sliding structure through a linear sliding block 12 and a linear sliding groove 6, and the linear sliding block 12 is embedded and installed inside the linear sliding groove 6; the adjusting rod 15 and the limiting column 14 form an elastic telescopic structure through an adjusting spring 16, and the adjusting rod 15 is fixedly arranged at the side position of the side inner protective shell 7;

the device is correspondingly arranged outside the Murphy's dropper, the outer protective shell 1 and the inner protective shell 7 of the side are pressed inwards to enable the inner protective shell 7 of the side and the outer protective shell 1 to correspondingly slide in a staggered mode through the linear sliding block 12 and the linear sliding groove 6, the outer protective shell 1 and the inner protective shell 7 of the side are mutually clamped to be in the closest state at the moment, the adjusting rod 15 is moved in a telescopic adjusting mode on the side face of the limiting column 14 to control the adjusting spring 16 to be compressed tightly, the outer limiting groove 5 and the inner limiting groove 10 are correspondingly communicated to be in the maximum state, the device is clamped outside the Murphy's dropper through the communicated outer limiting groove 5 and the inner limiting groove 10, then the pressing force degree of the device is loosened, at the moment, under the elastic thrust action of the adjusting spring 16, the adjusting rod 15 slides out from the side face of the limiting column 14, the side face of the inner protective shell 7 slides outwards towards the side face of the outer protective shell 1, the outer limiting groove 5 and the inner limiting groove 10 are mutually staggered, the device is controlled to be quickly clamped outside the Murphy's dropper through the outer limiting groove 5 and the inner limiting groove 10, and the device is conveniently installed and controlled.

The inner limiting groove 10 and the outer limiting groove 5 are communicated and correspond to each other, and the inner side surfaces of the inner limiting groove 10 and the outer limiting groove 5 are in arc-shaped structures; the infrared inductor 11 is arranged on the inner side arc surface of the inner limiting groove 10, and the inner side and the outer side of the infrared inductor 11 are both in arc-shaped structures;

set up the device block in the outside of Murphy's burette after, 11 blocks of infrared inductor set up the outside at Murphy's burette this moment, the inside infusion of Murphy's burette gradually drops downwards, under infrared inductor 11's induction action, can detect the dripping speed of interval dropping liquid in real time, infrared inductor 11 transmits the data that detect to built-in calculation chip 2, and built-in calculation chip 2 passes through display screen 3 control data outwards output with the data that calculate, medical staff can be directly observe the real-time dripping speed of Murphy's burette through display screen 3, it is very convenient to detect the application, and device application cost is lower.

The working principle is as follows: when the device is used, according to the structure shown in the figures 1-5, the outer protective shell 1 and the inner protective shell 7 on the side are pressed inwards to control the relative sliding between the two, at the moment, the outer limiting groove 5 and the inner limiting groove 10 are communicated with each other, the device is controlled to be clamped and arranged outside the Murphy's dropper through the communicating structure, the inner protective shell 7 on the side is enabled to slide outwards under the action of the elastic thrust of the adjusting spring 16, the outer limiting groove 5 and the inner limiting groove 10 are mutually staggered, the infrared inductor 11 is clamped and arranged outside the Murphy's dropper, the control device is quickly clamped and arranged outside the Murphy's dropper, the real-time dropping speed of the infusion inside the Murphy's dropper is sensed through the infrared inductor 11, and the control data is output outwards through the display screen 3 after the built-in computing chip 2 is computed, so that medical personnel can conveniently observe the dropping speed, and the application is convenient.

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

Claims (6)

1. A small real-time dripping speed display comprises components arranged inside an outer protective shell (1) and an inner protective shell (7) on the side, wherein the inner protective shell (7) on the side is embedded inside the side surface of the outer protective shell (1);

it is characterized by comprising:

the built-in computing chip (2) is fixedly embedded in the outer protective shell (1), a display screen (3) is fixedly embedded on one side of the upper surface of the outer protective shell (1), and a battery panel (4) is embedded on one side of the lower surface of the outer protective shell (1);

the outer limiting groove (5) penetrates through the inner part of the outer protective shell (1), and the upper surface of the outer protective shell (1) is provided with a linear sliding groove (6);

the connector (8) is fixedly arranged on the upper surface of the side inner protective shell (7), one side of the connector (8) is embedded and correspondingly arranged on the side surface of the outer protective shell (1), and the side surface of the connector (8) is electrically connected with a connecting cable (9);

and the inner limiting groove (10) penetrates through the inner side of the side inner protective shell (7), and an infrared inductor (11) is arranged on the side surface of the inner limiting groove (10).

2. A small real-time droplet rate display according to claim 1, wherein: the built-in circuit protection block (13) is embedded and fixed in the outer protection shell (1), limiting columns (14) are symmetrically fixed at two ends of the side face of the built-in circuit protection block (13), adjusting rods (15) are connected in the side faces of the limiting columns (14), and the adjusting rods (15) are connected with the limiting columns (14) through adjusting springs (16).

3. A small real-time droplet rate display according to claim 1, wherein: protective housing (7) constitutes gomphosis extending structure with outer protective housing (1) in the avris, just protective housing (7) constitutes sharp sliding structure through sharp slider (12) and sharp spout (6) with outer protective housing (1) in the avris, the inside at sharp spout (6) is installed in sharp slider (12) gomphosis.

4. A small real-time droplet rate display according to claim 1, wherein: the inner limiting groove (10) and the outer limiting groove (5) are communicated and correspond to each other, and the inner side surfaces of the inner limiting groove (10) and the outer limiting groove (5) are of arc-shaped structures.

5. A small real-time droplet rate display according to claim 1, wherein: the infrared sensor (11) is arranged on the inner side arc surface of the inner limiting groove (10), and the inner side and the outer side of the infrared sensor (11) are of arc-shaped structures.

6. A small real-time droplet rate display according to claim 2, wherein: the adjusting rod (15) and the limiting column (14) form an elastic telescopic structure through an adjusting spring (16), and the adjusting rod (15) is fixedly installed on the side surface of the side inner protective shell (7).

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