CN221044951U - Electrocardiogram lead positioning belt - Google Patents

Abstract

The utility model belongs to the technical field of medical appliances, and discloses an electrocardiogram lead positioning belt, which comprises six electrodes, six wires and a protection pad, wherein a spring bolt wire is electrically connected with the electrodes, and the electrocardiogram lead positioning belt further comprises: the number of the binding buckles is two, and the binding buckles are arranged at the left end of the protection pad; the number of the binding bands is two, the binding bands are arranged at the right end of the protection pad, and the binding bands can be buckled and connected with the binding bands; the magic female patch is arranged on the front side surface of the protection pad; the magic male paste is stuck to the rear side of the electrode, and the magic male paste is stuck to the magic female paste; the number of the tensile mechanisms is six, and the tensile mechanisms are arranged at the top of the protection pad from left to right. When in actual use, can realize the fixed of electrode and wire, can not cause the electrode to take place the displacement when touching the wire in patient's first aid or the transfer in-process, patient's sign monitoring is stable, and the accuracy is high, avoids causing the misleading to medical personnel rescue.

Description

Electrocardiogram lead positioning belt

Technical Field

The utility model belongs to the technical field of medical appliances, and particularly relates to an electrocardiogram lead positioning belt.

Background

Electrocardiograph is invented by William Airtight. The electrocardiograph can automatically record bioelectric signals (electrocardiosignals) generated by myocardial activation during heart activity, and is a medical electronic instrument commonly used for clinical diagnosis and scientific research. An electrocardiogram has four limb leads and six chest leads. When an electrocardiogram is made, the lead electrodes in front of the electrodes V1 are respectively fixed between the fourth ribs on the right edge of the sternum, between the fourth ribs on the left edge of the sternum of the electrodes V2, the electrode V3 is at the end point of the connecting line between the V2 and the V4, the electrode V4 is at the intersection between the collarbone midline and the fifth rib, the electrode V5 is at the level of the left anterior axillary line V4, and the electrode V6 is at the level of the left anterior axillary midline V4;

The prior art has the following defects:

The electrocardiographic examination is mainly used under two conditions of normal physical examination and first aid, when the first aid condition occurs, the leads are easily torn in the process of patient rescue and transfer due to the fact that the leads are numerous, the electrodes are adsorbed in front of the chest of the patient by the sucker, the fixing effect is limited, the leads can be caused to displace, normal monitoring of the physical signs of the patient can not be implemented, and medical staff can be misled to rescue.

Disclosure of utility model

In order to solve the problems that the lead electrode is unstable in fixation and the accuracy of monitoring the physical sign of a patient is reduced once the electrode is displaced in the prior art. The utility model provides an electrocardiogram lead positioning belt.

The utility model is realized in such a way that the electrocardiogram lead positioning belt comprises six electrodes, six leads and a protection pad, wherein the leads are electrically connected with the electrodes, and the electrocardiogram lead positioning belt further comprises: the number of the binding buckles is two, and the binding buckles are arranged at the left end of the protection pad; the number of the binding bands is two, the binding bands are arranged at the right end of the protection pad, and the binding bands can be buckled and connected with the binding bands; the magic female patch is arranged on the front side surface of the protection pad; the magic male paste is stuck to the rear side of the electrode, and the magic male paste is stuck to the magic female paste; the number of the tensile mechanisms is six, the tensile mechanisms are arranged at the top of the protection pad from left to right, and the tensile mechanisms can clamp the wires.

Further, an air bag is arranged between the protection pad and the magic female patch.

Still further, an object is to clamp the wire in place, promote wire resistance to plucking, prevent to pull the electrode, the tensile mechanism includes: the first clamping plate is fixedly connected to the top of the protection pad, and a groove is formed in the front side of the first clamping plate; the second clamping plate is connected to the rear side of the first clamping plate through a hinge; the number of the bolts is two, the bolts are respectively and fixedly connected to the upper end and the lower end of the front side of the second clamping plate, the bolts are inserted into the grooves of the first clamping plate, and the middle part of each bolt is provided with a positioning hole; and the clamping assembly is arranged on the front side of the first clamping plate along the up-down direction, and is matched with the lock tongue to position the second clamping plate.

Further, the inner walls of the first clamping plate and the second clamping plate are provided with anti-slip edges from top to bottom.

Still further, the snap assembly includes: the limiting shell is arranged at the front side of the first clamping plate along the up-down direction; the push-pull plate can be inserted into the inner cavity of the limiting shell in a forward-backward sliding way; the number of the springs is two, and the springs are respectively arranged at the upper end and the lower end of the front side of the push-pull plate; the number of the clamping blocks is two, the clamping blocks are respectively arranged at the upper end and the lower end of the rear side of the push-pull plate, and the clamping blocks are inserted into the inner cavities of the positioning holes under the action of the elasticity of the springs.

Further, the rear side of the clamping block is inclined.

Compared with the prior art, the utility model has the beneficial effects that: the electrode position is adjusted by moving the magic tape on the magic tape, the protection pad can be fixed in front of the chest of a patient by tightening the binding tape and the binding tape, after the air bag is inflated, the electrode is tightly attached to the chest of the patient, electrocardiographic monitoring is realized, the lead is placed between the first clamping plate and the second clamping plate, the second clamping plate is closed, the lock tongue extrudes the inclined surface of the lock block, the lock block can drive the push-pull plate to move towards the front side until the lock tongue enters the groove of the first clamping plate, the spring pushes the lock block to move towards the rear side under the action of self elasticity and insert into the positioning hole, the second clamping plate is fixed, and therefore, the fixation of the electrode and the lead can be realized by matching the first clamping plate with the second clamping plate, the electrode is not displaced when the lead is touched in the process of first aid or transfer of the patient, the physical sign monitoring of the patient is stable, the accuracy is high, and the lead is prevented from being mistakenly caused by the rescue of medical staff.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a top cross-sectional view of the pad of the present utility model;

FIG. 3 is a top cross-sectional view of the tensile mechanism of the present utility model;

FIG. 4 is an enlarged view of the utility model at A;

fig. 5 is a left side cross-sectional view of the snap-action assembly of the present utility model.

In the figure: 1. an electrode; 2. a wire; 3. a protective pad; 4. a binding belt buckle; 5. a strap; 6. magic mother plaster; 7. magic tape; 8. a tensile mechanism; 9. an air bag; 81. a first clamping plate; 82. a second clamping plate; 83. a bolt; 84. positioning holes; 85. a blocking component; 851. a limit shell; 852. a push-pull plate; 853. a spring; 854. and (5) clamping blocks.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1-5, the present utility model provides the following technical solutions: the electrocardiogram lead positioning belt comprises six electrodes 1, six leads 2 and a protection pad 3, wherein the leads 2 are electrically connected with the electrodes 1, and the electrocardiogram lead positioning belt further comprises a binding belt buckle 4, a binding belt 5, a magic female patch 6, a magic male patch 7 and a tensile mechanism 8, wherein the number of the binding belt buckles 4 is two, and the binding belt buckles are both arranged at the left end of the protection pad 3; the number of the binding bands 5 is two, the two binding bands 5 are arranged at the right end of the protection pad 3, and the binding bands 5 can be bound with the binding band buckles 4, so that the protection pad 3 can be fixed in front of the chest of a patient; the magic mother plaster 6 is arranged on the front side surface of the protection pad 3; the magic tape 7 is stuck to the rear side of the electrode 1, the magic tape 7 is stuck to the magic female tape 6, and the magic tape 7 moves on the magic female tape 6, so that the position of the electrode 1 is changed, and the electrode 1 is placed at a chest measurement point; the number of the tensile mechanisms 8 is six, the tensile mechanisms 8 are arranged at the top of the protection pad 3 from left to right, and the tensile mechanisms 8 can clamp the lead 2;

According to patient stature, move the public subsides 7 of magic on the female subsides 6 of magic, make electrode 1 correspond patient's chest measuring point, protection pad 3 twines in patient's chest, make protection pad 3 fixed through bandage 5 and bandage knot 4 cooperation, aerify in the gasbag 9, gasbag 9 extrudees electrode 1 and pastes at patient's chest, realizes primary fixed to electrode 1, electrode 1 and patient's chest contact, wire 2 is connected with the electrocardiograph, carries out patient's physical sign monitoring.

As the preferable scheme, still further, install gasbag 9 between protection pad 3 and the female subsides of magic 6, gasbag 9 aerify the back, gasbag 9 can extrude electrode 1 and patient's chest contact all the time, guarantees electrocardiograph measurement accuracy.

As a preferred scheme, the tensile mechanism 8 comprises a first clamping plate 81, a second clamping plate 82, a lock tongue 83, a positioning hole 84 and a blocking component 85, wherein the first clamping plate 81 is fixedly connected to the top of the protection pad 3, a groove is formed in the front side of the first clamping plate 81, the inner sides of the first clamping plate 81 and the second clamping plate 82 are semicircular and are matched with the outer wall of the wire 2 in shape, and the contact area during clamping is increased; the second clamping plate 82 is connected to the rear side of the first clamping plate 81 through a hinge; the number of the lock bolts 83 is two, the lock bolts 83 are respectively and fixedly connected to the upper end and the lower end of the front side of the second clamping plate 82, the lock bolts 83 are inserted into the grooves of the first clamping plate 81, and the middle part of the lock bolts 83 is provided with a positioning hole 84; the locking assembly 85 is installed at the front side of the first clamping plate 81 in the up-down direction, and the second clamping plate 82 is positioned by matching the locking assembly 85 with the locking tongue 83.

As a preferred scheme, still further, the inner wall of first splint 81 and second splint 82 all is provided with the antiskid arris from top to bottom, increases the frictional force of first splint 81 and second splint 82 centre gripping wire 2, and then promotes wire 2 resistance to plucking.

As a preferred solution, the locking assembly 85 includes a limit housing 851, a push-pull plate 852, a spring 853 and a clamping block 854, wherein the limit housing 851 is installed at the front side of the first clamping plate 81 along the up-down direction; the push-pull plate 852 can be inserted into the inner cavity of the limit shell 851 in a sliding way, and the push-pull plate 852 controls the clamping block 854 to move forwards and backwards; the number of the springs 853 is two, and the springs are respectively arranged at the upper end and the lower end of the front side of the push-pull plate 852; the number of the clamping blocks 854 is two, the clamping blocks 854 are respectively arranged at the upper end and the lower end of the rear side of the push-pull plate 852, and the clamping blocks 854 are inserted into the inner cavity of the positioning hole 84 under the elastic force of the spring 853 to position the lock tongue 83;

When the wire 2 needs to be fixed, the push-pull plate 852 is pulled forwards to enable the clamping block 854 to move forwards until the clamping block 854 moves out of the positioning hole 84, the positioning of the second clamping plate 82 is released, the second clamping plate 82 is separated from the first clamping plate 81, the wire 2 is placed between the first clamping plate 81 and the second clamping plate 82, the second clamping plate 82 is closed to enable the lock tongue 83 to enter the groove of the first clamping plate 81 and squeeze the clamping block 854, the clamping block 854 pushes the push-pull plate 852 to move forwards under the action of the inclined plane until the positioning hole 84 corresponds to the position of the clamping block 854, the spring 853 pushes the clamping block 854 to move backwards and be inserted into the positioning hole 84 under the action of the self elastic force through the push-pull plate 852, the fixing of the lock tongue 83 is achieved, the first clamping plate 81 and the second clamping plate 82 clamp the wire 2 are clamped and the wire 2 is prevented from being pulled to enable the electrode 1 to displace.

As a preferred scheme, still further, the rear side shape of the clamping block 854 is an inclined plane, when the lock tongue 83 presses the inclined plane of the clamping block 854, the clamping block 854 can automatically move forward, and the lock tongue 83 cannot be influenced to enter the groove of the first clamping plate 81.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (6)

1. An electrocardiogram lead positioning belt comprises six electrodes (1), six leads (2) and a protection pad (3), wherein the leads (2) are electrically connected with the electrodes (1), and the electrocardiogram lead positioning belt is characterized by further comprising:

The number of the binding buckles (4) is two, and the binding buckles are arranged at the left end of the protection pad (3);

The number of the binding bands (5) is two, the two binding bands are arranged at the right end of the protection pad (3), and the binding bands (5) can be bound with the binding band buckles (4);

the magic female plaster (6) is arranged on the front side surface of the protection pad (3);

The magic male patch (7) is stuck to the rear side of the electrode (1), and the magic male patch (7) is stuck to the magic female patch (6);

The number of the tensile mechanisms (8) is six, the tensile mechanisms (8) are arranged at the top of the protection pad (3) from left to right, and the tensile mechanisms (8) can clamp the wires (2).

2. An electrocardiogram lead positioning belt according to claim 1, characterized in that an air bag (9) is arranged between the protection pad (3) and the magic female plaster (6).

3. An electrocardiogram lead positioning tape according to claim 1, wherein the tension mechanism (8) comprises:

The first clamping plate (81) is fixedly connected to the top of the protection pad (3), and a groove is formed in the front side of the first clamping plate (81);

The second clamping plate (82) is connected to the rear side of the first clamping plate (81) through a hinge;

the number of the lock bolts (83) is two, the lock bolts are respectively and fixedly connected to the upper end and the lower end of the front side of the second clamping plate (82), the lock bolts (83) are inserted into the grooves of the first clamping plate (81), and the middle part of each lock bolt (83) is provided with a positioning hole (84);

And the blocking component (85) is arranged on the front side of the first clamping plate (81) along the up-down direction, and the second clamping plate (82) is positioned by matching the blocking component (85) with the lock tongue (83).

4. An electrocardiogram lead positioning tape according to claim 3, wherein the inner walls of the first clamping plate (81) and the second clamping plate (82) are provided with anti-slip ridges from top to bottom.

5. An electrocardiogram lead positioning tape according to claim 3, wherein the locking assembly (85) comprises:

A limit housing (851) installed at the front side of the first clamping plate (81) along the up-down direction;

The push-pull plate (852) can be inserted into the inner cavity of the limit shell (851) in a back-and-forth sliding manner;

The number of the springs (853) is two, and the springs are respectively arranged at the upper end and the lower end of the front side of the push-pull plate (852);

The number of the clamping blocks (854) is two, the clamping blocks are respectively arranged at the upper end and the lower end of the rear side of the push-pull plate (852), and the clamping blocks (854) are inserted into the inner cavity of the positioning hole (84) under the elastic force of the spring (853).

6. The electrocardiogram lead positioning belt according to claim 5, wherein the rear side of the clamping block (854) is shaped as an inclined plane.