CN207707966U - Electric intelligent arteria femoralis compression hemostat - Google Patents

Abstract

The utility model discloses a kind of electric intelligent arteria femoralis compression hemostats, main includes joint shell, the pulling force sensor being contained in joint shell, control panel and compression band that activity is positioned in joint shell and the compression bladder and buckle being set on compression band.The utility model discloses the pulling force for obtaining compression band to it by pulling force sensor, the included display screen of pulling force sensor can show that pulling force is read, it is estimated to take air bag pressing force size by pulling force reading, to which effectively adjustment air bag realizes the flexible compressing of point of puncture progress to femoral artery to the pressuring action at hemostasis and effectively stopped blooding.The utility model is simple in structure, compact, and patient can carry out simple leg movements and trunk activity when in use, avoids the discomforts such as the body numbness that patient quiet for a long time need to lie and immovable leg is brought, has good hommization.

Description

Electric intelligent femoral artery compression hemostat

Technical Field

The utility model relates to an intervene medical equipment technical field, especially relate to an electronic intelligent femoral artery hemostasis by compression ware.

Background

Interventional medicine is a subject which relies on the guidance of medical imaging equipment and utilizes puncture and catheter technology to diagnose and treat diseases, and mainly treats diseases. She has the characteristics of accurate positioning, small wound, few complications, high curative effect, quick response, strong repeatability and the like. Interventional therapy has become the third major clinical treatment means in parallel with medical and surgical treatment.

The most commonly selected method for vascular intervention is due to the advantages of large internal diameter of femoral artery, difficult damage to blood circulation, easy mastering of technology, capability of placing a large sheath tube according to requirements and the like. After the intervention operation, the puncture point of a patient needs to be subjected to compression hemostasis, the compression position is generally the root of the thigh, and the compression time is from ten minutes to half an hour. The femoral artery compression hemostasis device commonly used at present mainly comprises four structural forms, namely a bracket type structure, an air bag pressurization type structure, a belt type structure and a spring type structure. The bracket type femoral artery compression hemostasis device is mainly integrated on a sickbed or a protective tool, has obvious defects, namely cannot be synchronous with the motion of a patient, namely, the bracket type femoral artery compression hemostasis device is fixed, the patient can only be static but cannot move relative to the bracket type femoral artery compression hemostasis device, and the compression hemostasis time is long, so that inconvenience is brought to the patient. The femoral artery compression hemostasis device of gasbag pressurization formula compresses through the gasbag and stanchs, and this kind of hemostasis mode accessible oppression brings supplementary completion, and consequently the flexibility is extremely strong, and the shortcoming is difficult to hold the oppression of the gas filled volume of gasbag in order to realize suitable oppression power, often can only rely on doctor's experience to accomplish. The hemostasis is realized through binding, wrapping to the arteria femoralis hemostasis by compression device of belt, does not have two-fold with traditional "ten" hemostasis, though simple, the practicality is not strong, and the advantage is not outstanding. The spring type femoral artery compression hemostasis device realizes compression by a spring device, but the spring has different elasticity, so that the user is difficult to find the appropriate compression force, or the user can find the appropriate compression force by the experience of a doctor, so that the wide use is inconvenient.

Chinese patent CN201520565128.2 discloses a femoral artery electronic compression hemostat, which is characterized in that: the waist belt comprises a waist belt and a compression belt, wherein the lower edge of the waist belt is fixedly connected with the upper edge part of the compression belt, an air bag is arranged at a compression hemostasis part on the inner side surface of the compression belt, and an electric control inflating device is fixedly arranged on the inner side surface of the waist belt or the compression belt and is communicated with the air bag. The utility model relates to a femoral artery electron hemostasis by compression ware, fixed simple and convenient carries out flexible oppression to femoral artery's puncture point, can artifical regulated pressure size moreover, and the design of more humanized has avoided the discomfort that equipment caused the patient, and it is effectual to stanch.

The femoral artery compression hemostasis device of gasbag pressurization formula that above-mentioned patent was proposed has solved the problem of femoral artery compression hemostasis device's flexibility well, and gasbag pressure is adjustable, has very humanized. However, the air pressure value of the air bag is still adjusted by the experience of medical staff, and the compression force of the air bag on the hemostasis part can only be estimated and felt, which is obviously not beneficial to the medical staff who initially contacts the device to use, thereby not being beneficial to the popularization and the use.

SUMMERY OF THE UTILITY MODEL

Not enough more than, the utility model provides an electronic intelligent femoral artery hemostasis by compression ware can roughly estimate gasbag compressive force size at the during operation to effective adjustment gasbag compresses tightly the effect and carries out flexible oppression and effectively stanch to femoral artery's puncture point in order to realize stanching the department.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an electric intelligent femoral artery compression hemostat comprises a connector shell, a tension sensor accommodated in the connector shell and an electric control device movably arranged in the connector shell; wherein,

the tension sensor is a sensor with a display function, a display screen of the tension sensor is positioned on the surface of the joint shell, and the tension sensor is fixedly connected with a compression belt;

the other end of the compression band is fixedly connected with the electric control equipment, the middle part of the compression band is connected through a buckle, and a compression air bag which is positioned at a compression hemostasis position when in use is arranged on the compression band;

when the electric control equipment is used, the electric control equipment is positioned in the connector shell to realize that the connector shell, the tension sensor, the compression belt and the electric control equipment form a closed structure, and the electric control equipment operates to roll the compression belt to realize compression of the compression air bag on a compression hemostasis position by tightening the closed structure formed by the connector shell, the tension sensor, the compression belt and the electric control equipment.

Preferably, the electric control equipment comprises a power supply, a micro motor, a control switch and an electric control equipment shell, wherein the power supply, the micro motor and the control switch are connected through a circuit, the power supply and the micro motor are arranged in the electric control equipment shell, and the control switch is arranged on the surface of the electric control equipment shell; the output shaft of the micro motor extends out of the shell of the electric control equipment and is connected with the compression belt.

Preferably, the compression air bag is fixedly arranged on the compression belt;

or movably arranged on the compression band in a binding or sticking way.

Preferably, the joint housing is arcuate.

Preferably, a flexible soft patch or foam pad is disposed on the curved concave side of the joint housing.

Preferably, the compression band is made of inelastic composite cloth.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses an electronic intelligent femoral artery hemostasis by compression ware acquires the pulling force of oppression area to it through force sensor, and force sensor can show the pulling force reading from the display screen of taking, estimates gasbag clamping force size through the pulling force reading to effective adjustment gasbag compresses tightly the effect and carries out flexible oppression and effectively stanch the puncture point of femoral artery in order to realize stanching the department. The utility model discloses simple structure, compactness, patient can carry out simple shank activity and truck activity when using, avoided patient to need quiet for a long time to lie and can not remove the discomfort such as health numbness that the shank brought, have fine hommization.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below.

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

FIG. 2 is a schematic structural diagram of an electronic control device;

fig. 3 is a schematic view of the connection of the electric control device and the compression band.

Wherein the labels shown in the figures are: 1: a connector housing; 2: a tension sensor; 21: a display screen; 3: an electronic control device; 31: a power source; 32: a micro motor; 33: a control switch; 34: an electric control equipment housing; 4: a compression band; 5: compressing the air bag; 6: and (5) buckling.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It is to be understood that the embodiments described are only some embodiments of the invention, and 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 belong to the protection scope of the present invention.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by the terms "inside" and the like are based on the directions or positional relationships shown in the drawings, or the directions or positional relationships that the products of the present invention are conventionally placed when used, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element to be referred to must have a specific direction, be constructed and operated in a specific direction, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be further noted that, unless otherwise explicitly specified or limited, the terms "disposed," "connected," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1, fig. 2 and fig. 3, the utility model provides an electric intelligent femoral artery compression hemostat, which mainly comprises a joint housing 1, a tension sensor 2 accommodated in the joint housing 1, an electric control device 3 movably arranged in the joint housing 1, a compression band 4, a compression air bag 5 arranged on the compression band and a buckle 6.

As shown in fig. 1, the joint housing 1 is curved, the concave side of the arc being the side facing the thigh, preferably with a curvature similar to the curvature of the outer circumference of a conventional thigh. In a preferred embodiment, the curved concave side of the joint housing 1 is provided with a flexible soft patch or foam pad that increases the comfort level for which the device is suitable.

As shown in fig. 1, the tension sensor 2 is a sensor with a display function, a display screen 21 of the tension sensor 2 is located on the surface of the joint housing 1, and the tension sensor 2 is fixedly connected with a compression belt 4. The tension sensor 2 obtains the tension of the compression belt 4, the display screen 21 of the tension sensor 2 can display tension readings, the pressing force of the compression air bag 5 is estimated according to the tension readings, namely, due to the tensioning effect of the compression belt 4, the tension sensor 2 is subjected to certain tension, an empirical formula of the tension applied to the tension sensor 2 and the pressing force of the compression air bag 5 is obtained and calculated through tests and the like, and the function of obtaining the pressing force of the compression air bag 5 through reading the tension readings can be achieved through certain conversion.

As shown in fig. 1, the other end of the compression band 4 is fixedly connected to the electric control device 3, the middle part of the compression band 4 is connected by a buckle 6, and the compression band 4 is provided with a compression air bag 5 which is located at a compression hemostasis position when in use.

In some preferred embodiments, the compression air bag 5 is fixedly arranged on the compression belt 4, the compression belt 4 is made of inelastic composite cloth, and the compression belt is not deformed after being used for a long time, so that the compression reliability of the compression air bag 5 is ensured; in some preferred embodiments, the compression bladder 5 may be removably attached to the compression band 4 by binding or adhering. The movable arrangement mode can facilitate the replacement of the compression air bag 5, namely only the compression air bag 5 needs to be replaced, and other parts of the utility model can be reused, thereby playing the role of saving cost; the oppression gasbag 5 that the activity set up still has the effect of adjusting the position, because the thigh circumference of different crowds varies in size, differs greatly even, consequently sets up the oppression gasbag 5 of activity and is favorable to the utility model is suitable for a on the different crowds.

In this embodiment, the compression airbag 5 is movably attached to the compression band 4 by means of adhesion. The sticking mode is a conventional snap-fit connection mode, and has two options: one is that the connecting surface of the compression air bag 5 is a suede surface, and the connecting surface of the compression belt 4 is a hook surface; the other is that the connecting surface of the pressing air bag 5 is a hook surface, and the connecting surface of the pressing belt 4 is a pile surface.

As shown in fig. 1, the electronic control device 3 is located in the connector housing 1 when in use to realize that the connector housing 1, the tension sensor 2, the compression band 4 and the electronic control device 3 form a closed structure, and the electronic control device 3 operates to roll up the compression band 4 to realize the compression of the compression balloon 5 on the compression hemostasis part by tightening the closed structure formed by the connector housing 1, the tension sensor 2, the compression band 4 and the electronic control device 3. When the connector is not used, the electronic control device 3 can be taken out from the connector housing 1, and after the electronic control device is taken out, the coiled part pressing belt 4 can be manually loosened from the electronic control device 3. The electrical control device 3 and the connector housing 1 are preferably in a plug-in mode to facilitate the pick-and-place of the electrical control device 3 on the connector housing 1.

As shown in fig. 2 and 3, in the preferred embodiment, the electric control device 3 includes a power source 31, a micro motor 32, a control switch 33, and an electric control device housing 34, the power source 31, the micro motor 32, and the control switch 33 are connected through a circuit, the power source 31 and the micro motor 32 are disposed in the electric control device housing 34, and the control switch 33 is disposed on a surface of the electric control device housing 34; the output shaft of the micro motor 32 extends out of the electronic control device housing 34 and is connected to the compression belt 4. The operation or the stop of the micro motor 32 is controlled by opening the control switch 33, when the micro motor 32 operates, the output shaft of the micro motor 32 rotates to roll the compression belt 4, so that the closed structure formed by the connector shell 1, the tension sensor 2, the compression belt 4 and the electric control equipment 3 is tightened, and the compression air bag 5 gradually increases the compression of the hemostasis to be compressed through the continuous tightening of the closed structure formed by the connector shell 1, the tension sensor 2, the compression belt 4 and the electric control equipment 3. In the process that a closed structure formed by the connector shell 1, the tension sensor 2, the compression band 4 and the electric control equipment 3 is continuously tightened, the compression band 4 can apply a continuously increased tension to the tension sensor 2, the tension sensor 2 can detect the tension and display the reading through a display screen 21 arranged on the tension sensor 2, the pressing force of the compression air bag 5 on a to-be-stopped part can be roughly estimated through the reading, when a certain tension value is reached, namely the pressing force of the compression air bag 5 on the to-be-stopped part reaches a certain magnitude, the micro motor 32 is stopped through the control switch 33, and the compression air bag 5 can realize a certain and continuous compression effect on the to-be-stopped part.

The utility model discloses a theory of operation is: when in use, the electric control device 3 is placed into the connector shell 1, the tension sensor 2, the compression band 4 and the electric control device 3 form a closed structure at the moment, the electric control device 3 is operated to roll the compression band 4, the closed structure formed by the connector shell 1, the tension sensor 2, the compression band 4 and the electric control device 3 is continuously tightened at the moment, so that the compression air bag 5 on the compression band 4 gradually increases the compression of a to-be-compressed hemostatic part, according to the correlation between the tension value of the tension sensor 2 and the pressing force of the pressing air bag 5 on the position to be pressed for hemostasis, when the value measured by the tension sensor 2 matches the value of the desired pressing force against the airbag 5, the electronic control device 3 is stopped, at the moment, the compression air bag 5 can keep a certain and continuous compression effect on the part to be stopped, and the compression hemostasis of the femoral artery can be realized through the continuous effect; after waiting a period of time, can be affirmed as having stanched, through opening buckle 6 on the oppression area 4, can realize oppression area 4 in the disconnection of buckle 6 department, can with the utility model discloses take off from the patient leg. After the compression hemostasis is completed, the electric control device 3 can be taken down from the connector shell 1.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (6)

1. An electric intelligent femoral artery compression hemostat is characterized by comprising a joint shell (1), a tension sensor (2) accommodated in the joint shell (1), and an electric control device (3) movably arranged in the joint shell (1); wherein,

the tension sensor (2) is a sensor with a display function, a display screen (21) of the tension sensor (2) is positioned on the surface of the joint shell (1), and the tension sensor (2) is fixedly connected with a compression belt (4);

the other end of the compression belt (4) is fixedly connected with the electric control equipment (3), the middle part of the compression belt (4) is connected through a buckle (6), and a compression air bag (5) which is positioned at a compression hemostasis position when in use is arranged on the compression belt (4);

when the electric control device (3) is used, the electric control device (3) is located in the connector shell (1) to enable the connector shell (1), the tension sensor (2), the compression belt (4) and the electric control device (3) to form a closed structure, and the electric control device (3) operates to roll up the compression belt (4) to enable the compression air bag (5) to compress a compression hemostasis position by tightening the closed structure formed by the connector shell (1), the tension sensor (2), the compression belt (4) and the electric control device (3).

2. The electric intelligent femoral artery compression hemostat according to claim 1, wherein the electric control device (3) comprises a power source (31), a micro motor (32), a control switch (33) and an electric control device shell (34), the power source (31), the micro motor (32) and the control switch (33) are connected through a circuit, the power source (31) and the micro motor (32) are arranged in the electric control device shell (34), and the control switch (33) is arranged on the surface of the electric control device shell (34); the output shaft of the micro motor (32) extends out of the electric control equipment shell (34) and is connected with the compression belt (4).

3. The electrically powered intelligent femoral artery compression hemostat according to claim 1, characterized in that the compression balloon (5) is fixedly arranged on the compression band (4);

or is movably arranged on the compression belt (4) in a binding or sticking way.

4. The electrically powered intelligent femoral artery compression hemostat according to claim 1, characterized in that the joint housing (1) is arc-shaped.

5. The electrically powered intelligent femoral artery compression hemostat according to claim 1, characterized in that a flexible soft patch or sponge pad is arranged on the arc-shaped concave side of the joint housing (1).

6. The electrically operated intelligent femoral artery compression hemostat according to claim 1, characterized in that the compression band (4) is made of inelastic composite cloth.