CN210144700U

CN210144700U - Make things convenient for pressing hemostasis device that intracardiac branch of academic or vocational study used

Info

Publication number: CN210144700U
Application number: CN201920227421.6U
Authority: CN
Inventors: 陈胜德; 郑太金; 吴俊锋; 彭庆英
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-02-22
Filing date: 2019-02-22
Publication date: 2020-03-17
Anticipated expiration: 2029-02-22

Abstract

The utility model discloses a press hemostasis device that makes things convenient for intracardiac branch of academic or vocational study to use, including casing, bandage and buckle, the equal joint in the left and right sides of casing has the one end of bandage, the other end joint of bandage has the buckle, the top central point of casing puts the joint has first bracing piece, the top welding of first bracing piece has the horizontal pole, the welding of the inner chamber top of first bracing piece has first spring, the bottom welding of first spring has first connecting block, the bottom welding of first connecting block has the second bracing piece, the bottom of second bracing piece runs through first bracing piece and extends the lower terminal surface of casing, the bottom joint of second bracing piece has the bottom plate. This make things convenient for hemostasis by pressing device that intracardiac branch of academic or vocational study used, the device can effectually intervene the treatment wound to the intracardiac branch of academic or vocational study and press the hemostasis, has alleviateed medical staff's burden, has improved the practicality of pressing hemostasis device, more accords with the user demand of reality.

Description

Make things convenient for pressing hemostasis device that intracardiac branch of academic or vocational study used

Technical Field

The utility model relates to a medical internal medicine technical field specifically is a press hemostasis device that makes things convenient for intracardiac branch of academic or vocational study to use.

Background

Can adopt the mode of interveneeing the treatment under the current intracardiac branch of academic or vocational study treatment under the many situations, it will treat the medicine and directly send to the affected part to get into the artery blood vessel through the seal wire puncture, although the wound of this kind of mode of interveneeing treatment intracardiac branch of academic or vocational study disease is little, danger is low, but the artery blood vessel is intervened to the pipe or the in-process that the treatment back pipe was taken out from, hemorrhage phenomenon appears very likely, consequently, generally can cooperate hemostasis device in the intracardiac branch of academic or vocational study intervention treatment, current hemostasis device for the intracardiac branch relies on the artifical manual operation of medical staff, dynamics and intermittent type time all are wayward, can influence hemostatic effect, simultaneously difficult regulation, the.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a make things convenient for pressing hemostasis device that intracardiac branch of academic or vocational study used to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a pressing hemostasis device convenient for cardiology department comprises a shell, a bandage and a buckle, wherein one end of the bandage is clamped on the left side and the right side of the shell, the buckle is clamped on the other end of the bandage, a first support rod is clamped on the top center of the shell, a cross rod is welded on the top end of the first support rod, a first spring is welded on the top end of the inner cavity of the first support rod, a first connecting block is welded on the bottom end of the first spring, a second support rod is welded on the bottom end of the first connecting block, the bottom end of the second support rod penetrates through the first support rod and extends out of the lower end face of the shell, a bottom plate is clamped on the bottom end of the second support rod, clamp holes are formed in the left side and the right side of the outer wall of the second support rod from top to bottom, a pull rod is sleeved on the outer wall of the first support rod, and, the welding of the outside of second spring has the second connecting block, the welding of the bottom of second connecting block has the round bar, the bottom of round bar extends into the inner chamber of casing and welds the connecting plate, the inboard welding of connecting plate have with calorie hole assorted dop, the outer wall bottom interference fit of round bar has the baffle, the inner chamber of the inner chamber top spout of casing is embedded to have the slider, and the slider cup joints in the outer wall of round bar, the outer wall of round bar has cup jointed the third spring, and the upper and lower both ends of third spring respectively with the lower terminal surface of slider and the up end looks joint of baffle.

Preferably, the number of the second connecting blocks is two, and the two second connecting blocks are symmetrically arranged relative to the first supporting rod.

Preferably, the clamping holes are arranged on the left side and the right side of the outer wall of the second supporting rod in a clearance mode, and the distance between every two adjacent clamping holes is 1 cm.

Preferably, the connecting plate is located at the bottom end of the baffle.

Preferably, the number of the sliding blocks is two, and the two sliding blocks are symmetrically arranged relative to the second supporting rod.

Compared with the prior art, the beneficial effects of the utility model are that: the pressing hemostasis device convenient for cardiology department drives the round rod, the baffle and the connecting plate to move upwards by pulling the cross rod upwards, when the round rod drives the baffle and the connecting plate to move upwards to the maximum distance, the elastic force of the second spring which recovers deformation pushes the clamping heads to be clamped into the inner cavities of the corresponding clamping holes, the external force applied to the cross rod is removed, the round rod, the baffle plate and the connecting plate are pushed to move downwards by the elastic force of the third spring which is restored to deform, a user repeatedly pulls the cross rod upwards and releases the cross rod to enable the second supporting rod to drive the bottom plate to move downwards to press and stop bleeding of the puncture part of the patient, the device can effectually press hemostasis to the internal medicine intervention treatment wound, and hemostatic effect is better, and convenient to use, the flexible operation has alleviateed medical staff's burden, has improved the practicality of pressing hemostasis device, more accords with actual user demand.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a cross-sectional view of the support rod of the present invention;

FIG. 3 is an enlarged view of the point A of the present invention;

fig. 4 is a cross-sectional view of the pull rod of the present invention.

In the figure: 1. the casing, 2, the bandage, 3, the buckle, 4, first bracing piece, 5, the horizontal pole, 6, first spring, 7, first connecting block, 8, second bracing piece, 9, the bottom plate, 10, the card hole, 11, the pull rod, 12, the second spring, 13, the second connecting block, 14, round bar, 15, the connecting plate, 16, the dop, 17, the baffle, 18, the third spring, 19, the slider.

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 work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a pressing hemostasis device convenient for cardiology department comprises a shell 1, a bandage 2 and a buckle 3, wherein one end of the bandage 2 is clamped on the left side and the right side of the shell 1, the buckle 3 is clamped on the other end of the bandage 2, a first supporting rod 4 is clamped on the top center of the shell 1, a cross rod 5 is welded on the top end of the first supporting rod 4, a first spring 6 is welded on the top end of an inner cavity of the first supporting rod 4, the first spring 6 is a spiral spring, the elastic coefficient is 19N/CM, the first spring 6 generates elastic deformation after being stretched or extruded and recovers to an initial state after external force is removed, a first connecting block 7 is welded on the bottom end of the first spring 6, a second supporting rod 8 is welded on the bottom end of the first connecting block 7, the bottom end of the second supporting rod 8 penetrates through the first supporting rod 4 and extends out of the lower end face of the shell 1, a bottom plate 9 is clamped on, the left side and the right side of the outer wall of the second support rod 8 are both provided with clamping holes 10 from top to bottom, the outer wall of the first support rod 4 is sleeved with a pull rod 11, the cross rod 11 drives the round rod 14, the baffle 17 and the connecting plate 15 to move upwards by pulling the cross rod 11 upwards, after the round rod 14 drives the baffle 17 and the connecting plate 15 to move upwards to the maximum distance, the elastic force which is restored to deformation through the second spring 12 pushes the chuck 16 to be clamped into the inner cavity of the corresponding clamping hole 10, the external force applied to the cross rod 11 is removed, the elastic force which is restored to deformation through the third spring 18 pushes the round rod 14, the baffle 17 and the connecting plate 15 to move downwards, a user repeatedly pulls the cross rod 11 upwards and releases, the second support rod 8 drives the bottom plate 9 to move downwards to press and stop bleeding on the puncture part of a patient, the inner cavities on the left side and the right side of the pull, the elastic coefficient is 20N/CM, the second spring 12 generates elastic deformation after being stretched or extruded, and is restored to the initial state after external force is removed, the second connecting block 13 is welded on the outer side of the second spring 12, the round rod 14 is welded at the bottom end of the second connecting block 13, the round rod 14 is moved towards the outer side to enable the connecting plate 15 and the clamping head 16 to be moved out of the inner cavity of the clamping hole 10, the elastic force of deformation is restored through the first spring 6, the second supporting rod 8 and the bottom plate 9 are pulled to reset, the buckle 3 is opened, the device is convenient to take off from the body of a patient, the bottom end of the round rod 14 extends into the inner cavity of the shell 1 and is welded with the connecting plate 15, the clamping head 16 matched with the clamping hole 10 is welded on the inner side of the connecting plate 15, the cross rod 11 is enabled to drive the round rod 14, the baffle plate 17 and the connecting plate 15 to move upwards by pulling the cross rod 11, when the round bar 14 drives the baffle 17 and the connecting plate 15 to move upwards to the maximum distance, the elastic force which is restored to deform by the second spring 12 pushes the chuck 16 to be clamped into the inner cavity of the corresponding clamping hole 10, the external force applied to the cross bar 11 is removed, the second support bar 8 and the bottom plate 9 are conveniently pushed downwards by the elastic force which is restored to deform by the third spring 18, hemostasis is conveniently carried out on a puncture part, the baffle 17 is in interference fit with the bottom end of the outer wall of the round bar 14, the inner cavity of the chute at the top end of the inner cavity of the shell 1 is embedded with the sliding block 19, the sliding block 19 is sleeved on the outer wall of the round bar 14, the sliding block 19 plays a supporting role on the third spring 18, when the round bar 14 is pulled outwards, the round bar 14 is promoted to drive the sliding block 19, the third spring 18, the baffle 17, the connecting plate 15 and the chuck 16 to move outwards, and when the chuck 16 is moved out, pulling second bracing piece 8 and bottom plate 9 and reseing, the outer wall of round bar 14 has cup jointed third spring 18, and third spring 18 is coil spring, and the elastic coefficient is 18N/CM, and third spring 18 produces elastic deformation after receiving tensile or extrusion, resumes to initial condition after getting rid of external force, and the upper and lower both ends of third spring 18 respectively with the lower terminal surface of slider 19 and the up end looks joint of baffle 17.

As a preferred scheme, furthermore, the number of the second connecting blocks 13 is two, and the two second connecting blocks 13 are symmetrically arranged relative to the first supporting rod 4, so that the circular rod 14 moves outwards to enable the circular rod 14 to drive the connecting plate 15 and the chuck 16 to move out of the inner cavity of the clamping hole 10, the first spring 6 recovers the deformed elastic force, the second supporting rod 8 and the bottom plate 9 are pulled to reset, the buckle 3 is opened, and the device is conveniently taken down from the body of a patient.

As a preferred scheme, further, the clamping holes 10 are arranged on the left side and the right side of the outer wall of the second support rod 8 at intervals, the distance between adjacent clamping holes 10 is 1cm, the cross rod 11 is pulled upwards, the cross rod 11 drives the round rod 14, the baffle 17 and the connecting plate 15 to move upwards, after the round rod 14 drives the baffle 17 and the connecting plate 15 to move upwards to the maximum distance, the elastic force restored by the deformation of the second spring 12 pushes the chuck 16 to be clamped into the inner cavity of the corresponding clamping hole 10, the external force applied to the cross rod 11 is removed, the elastic force restored by the deformation of the third spring 18 pushes the round rod 14, the baffle 17 and the connecting plate 15 to move downwards, and a user repeatedly pulls the cross rod 11 upwards and releases the same, so that the second support rod 8 drives the bottom plate 9 to move downwards to press and stop bleeding of the puncture part.

As an optimized scheme, furthermore, the connecting plate 15 is located at the bottom end of the baffle 17, the cross rod 11 is pulled upwards to enable the cross rod 11 to drive the round rod 14, the baffle 17 and the connecting plate 15 to move upwards, the baffle 17 moves upwards and simultaneously extrudes the third spring 18, after the round rod 14 drives the baffle 17 and the connecting plate 15 to move upwards to the maximum distance, the elastic force restoring deformation of the second spring 12 pushes the clamping head 16 to be clamped into the inner cavity of the corresponding clamping hole 10, the external force applied to the cross rod 11 is removed, the elastic force restoring deformation of the third spring 18 conveniently pushes the second supporting rod 8 and the bottom plate 9 downwards, and hemostasis is conveniently performed on a puncture part.

As a preferred scheme, furthermore, the number of the sliding blocks 19 is two, the two sliding blocks 19 are symmetrically arranged relative to the second support rod 8, the sliding blocks 19 support the third spring 18, when the round rod 14 is pulled outwards, the round rod 14 is enabled to drive the sliding blocks 19, the third spring 18, the baffle 17, the connecting plate 15 and the chuck 16 to move outwards, and after the chuck 16 is moved out of the inner cavity of the chuck hole 10, the second support rod 8 and the bottom plate 9 are pulled to reset through the elastic force of the first spring 6 restoring the deformation.

The detailed connection means is a technique known in the art, and the following mainly describes the working principle and process, and the specific operation is as follows.

When the hemostatic bandage is used, a user opens the buckle 3, the bandage 2 is wound on the body of a patient, the shell 1 and the bottom plate 9 are placed at a position needing hemostasis, the buckle 3 is fastened and fixed, the user holds the cross rod 5, and pulls the cross rod 11 upwards with fingers to enable the cross rod 11 to drive the round rod 14, the baffle 17 and the connecting plate 15 to move upwards, the connecting plate 15 drives the chuck 16 to move upwards to be in contact with the inner wall of the clamping hole 10 and extrude the chuck 16 and the connecting plate 15 to move outwards, the connecting plate 15 drives the round rod 14, the baffle 17, the third spring 18, the sliding block 19 and the second connecting block 13 to move outwards to stretch the second spring 12, the second spring 12 is stressed and deformed to tighten the reverse tensile force to the second connecting block 13, the baffle 17 moves upwards while extruding the third spring 18, the third spring 18 is stressed and deformed to tighten the reverse thrust to the baffle 17, and the round rod 14 drives the baffle 17 and the connecting plate 15 to move upwards to the maximum distance and then push the clamp 12 The head 16 is clamped into the inner cavity of the corresponding clamping hole 10, the external force applied to the cross rod 11 is removed, the deformed elastic force is recovered through the third spring 18, the round rod 14, the baffle 17 and the connecting plate 15 are pushed to move downwards, the connecting plate 15 drives the second supporting rod 8 and the bottom plate 9 to move downwards through the clamping head 16 to stretch the first spring 6, the first spring 6 is stressed to deform and tighten the reverse tensile force for the second supporting rod 8, a user repeatedly pulls the cross rod 11 upwards and releases the cross rod, the second supporting rod 8 drives the bottom plate 9 to move downwards to press and stop bleeding for the puncture part of a patient, after the blood stopping is finished, the round rod 14 is moved outwards, the round rod 14 drives the connecting plate 15 and the clamping head 16 to move out of the inner cavity of the clamping hole 10, the second supporting rod 8 and the bottom plate 9 are pulled to reset through the deformed elastic force recovered by the first spring 6, the buckle 3 is opened, and the device is taken down, the device simple structure controls convenient to use, has improved the practicality of pressing hemostasis device, more accords with actual user demand.

Claims

1. The utility model provides a make things convenient for hemostasis by compression device that intracardiac branch of academic or vocational study used, includes casing (1), bandage (2) and buckle (3), the equal joint in the left and right sides of casing (1) has the one end of bandage (2), the other end joint of bandage (2) has buckle (3), its characterized in that: the top center of the shell (1) is provided with a first supporting rod (4) in a clamped mode, the top of the first supporting rod (4) is welded with a cross rod (5), the top of the inner cavity of the first supporting rod (4) is welded with a first spring (6), the bottom of the first spring (6) is welded with a first connecting block (7), the bottom of the first connecting block (7) is welded with a second supporting rod (8), the bottom of the second supporting rod (8) penetrates through the first supporting rod (4) and extends out of the lower end face of the shell (1), the bottom of the second supporting rod (8) is clamped with a bottom plate (9), clamping holes (10) are formed in the left side and the right side of the outer wall of the second supporting rod (8) from top to bottom, a pull rod (11) is sleeved on the outer wall of the first supporting rod (4), and second springs (12) are welded in the inner cavities in the left side and the right side of the pull rod, the outside welding of second spring (12) has second connecting block (13), the bottom welding of second connecting block (13) has round bar (14), the bottom of round bar (14) extends into the inner chamber and the welding of casing (1) has connecting plate (15), the inboard welding of connecting plate (15) has dop (16) with calorie hole (10) assorted, the outer wall bottom interference fit of round bar (14) has baffle (17), the inner chamber of the inner chamber top spout of casing (1) is embedded to have slider (19), and slider (19) cup joint in the outer wall of round bar (14), the outer wall of round bar (14) has cup jointed third spring (18), and the upper and lower both ends of third spring (18) respectively with the lower terminal surface of slider (19) and the up end looks joint of baffle (17).

2. A compression hemostasis device for facilitating cardiology procedures as claimed in claim 1, wherein: the number of the second connecting blocks (13) is two, and the two second connecting blocks (13) are symmetrically arranged relative to the first supporting rod (4).

3. A compression hemostasis device for facilitating cardiology procedures as claimed in claim 1, wherein: the clamping holes (10) are arranged on the left side and the right side of the outer wall of the second supporting rod (8) in a clearance mode, and the distance between every two adjacent clamping holes (10) is 1 cm.

4. A compression hemostasis device for facilitating cardiology procedures as claimed in claim 1, wherein: the connecting plate (15) is positioned at the bottom end of the baffle plate (17).

5. A compression hemostasis device for facilitating cardiology procedures as claimed in claim 1, wherein: the number of the sliding blocks (19) is two, and the two sliding blocks (19) are symmetrically arranged relative to the second supporting rod (8).