KR102026374B1 - Vessel expansion simulator - Google Patents

Abstract

The present invention can simulate in detail the phenomenon in which the blood vessels of a person swell when the tourniquet is tied to implement a vascular expansion that can provide a more realistic practice, as a means for achieving the above object, the elasticity of the elastic material pad; A blood vessel tube interposed on the elastic pad in a tube shape in which simulated blood flows; And a pressure plate rotatably installed on the lower surface of the casing, wherein the pressure plate rotates to press the lower surface of the elastic pad and the blood vessel tube.

Description

Intravenous injection simulator that can realize blood vessel expansion

The present invention relates to an intravenous injection simulator that can implement vasodilation, and more particularly, a vessel that can simulate the expansion of a human blood vessel when the tourniquet is tied in detail to provide a more realistic practice. It relates to an intravenous simulator that can implement dilation.

Dosing is for the purpose of safely injecting drugs into the human body by medical personnel or medical technicians (collectively referred to as users) and collectively refers to the use of drugs for the purpose of disease recovery, health promotion and disease prevention. Types of administration include topical application, inhalation, and swallowing, and methods of circulating the whole body include internal medicine, injection, and application.

At this time, if the dosage and administration route is inadequate, the patient may cause serious medical problems, so accurate dosage training is required for safe dosage. Injecting with the injection is generally intradermal injection to inject drugs by inserting the needle into the shallowest layer of the human body and subcutaneous injection to inject the drug by inserting the needle to the subcutaneous fat layer, injecting the drug directly into the muscle It is divided into intramuscular injection and intravenous injection to inject drugs by stabbing needles into blood vessels.

On the other hand, the intravenous injection is widely used in the injection of blood, electrolytes, etc. in addition to the injection of drugs into the body, such intravenous injection is a medical practice that must be familiar to the user.

When intravenous injection is applied clinically in the immature state of vein injection, the patient is exposed to problems such as pain and secondary injury when the needle is not correctly injected into the blood vessel.

In order to overcome the above problems, the user performs repetitive injection practice to increase the skill of intravenous injection or practice intravenous injection on a rubber or silicone model of a human body in which a vascular tube that simulates a human blood vessel is installed.

The conventional silicone model simply supplies a simulated blood to one vessel tube using a pump in one direction, so when installing a tourniquet for visual observation of blood vessel expansion, the supply of simulated blood is stopped on one side from the position where the tourniquet is installed. Therefore, there is a problem in that the expansion of the blood vessels can not be reproduced, and the effectiveness of the skill improvement is inferior when the training is conducted in the same manner as described above.

Patent Publication No. 10-2010-0122172

The present invention was created in view of the above-mentioned problems in the prior art, it is possible to practice the injection can feel the injection reaction force similar to the injection to the actual human limbs, as well as the blood vessel of the human It is an object of the present invention to provide an intravenous injection simulator and a method for manufacturing the same, which can simulate the expansion phenomenon in a realistic manner and can realize a blood vessel dilation that can perform a more realistic injection practice.

Means for achieving the above object, the elastic pad of the elastic material; A blood vessel tube interposed on the elastic pad in a tube shape in which simulated blood flows; And a pressure plate rotatably installed on the lower surface of the casing, wherein the pressure plate rotates to press the lower surface of the elastic pad and the blood vessel tube.

In addition, the pressure plate is in the shape of a lever, the intermediate plate is installed on the left and right sides of the rotation pin to act as a support point for the rotation pin; A lower plate attached to one side of the intermediate plate to receive a pressure of an elastic pad and act as a force point; And a rising plate attached to the other side of the intermediate plate and acting as a functioning point of the lowering plate through which pressure is transmitted. When the tourniquet is tied to one side of the simulator, one side of the elastic pad is pressed while the lowering plate acts as a force point. At the same time, while the rising plate acts as a functioning point, the elastic pad and the vascular tube at the same time to the upper portion characterized in that the expansion of the vascular tube.

The casing may further include a casing having an upper surface open to form an accommodation space therein, wherein the casing is fixed to at least one of a limb and a mannequin.

In addition, injection molding the silicon to form a dermal layer; Naturally curing the silicone to form an epidermal layer of lower hardness than the dermal layer; Providing a blood vessel tube through which the simulated blood flows; And inserting the vascular tube into the elastic pad to which the dermal layer and the epidermal layer are coupled and accommodating the casing.

In addition, the dermal layer is a silicone having a Shore hardness of 10 ~ 20A is used, the epidermal layer is manufactured of a training kit for injection molding capable of implementing the vascular expansion, characterized in that the silicone having a Shore hardness of 1 ~ 5A is used. Way.

Effects according to the present invention are as follows.

When the tourniquet is tied to the simulator, the expansion of the injection part can be visually confirmed by the lever action of the pressure plate, and thus the effect of carrying out a more realistic injection practice can be performed. There is an effect that acts to compress more effectively.

1 is a perspective view showing the overall appearance of the intravenous injector simulator according to the present invention.
2 to 3 is an exploded perspective view showing the overall appearance of the intravenous simulator in accordance with the present invention.
4 is a cross-sectional view of the AA line shown in FIG.
5 is a conceptual view for explaining the expansion of the vascular tube based on the cross section of the line BB shown in FIG.
Figure 6 is a perspective view showing the overall appearance to explain another embodiment of the intravenous injection simulator according to the present invention.
7 to 8 are exploded perspective view showing the overall appearance to explain another embodiment of the intravenous injection simulator according to the present invention.
9 is a conceptual diagram for explaining the concept of simulated blood flowing in the vascular tube.
10 is a cross-sectional view taken along line AA of FIG. 6.
FIG. 11 is a cross-sectional view of the BB line shown in FIG. 6. FIG.
12 is a conceptual diagram for explaining the operation of another embodiment of the intravenous simulator according to the present invention.
Figure 13 is a state of use of the intravenous injection simulator according to the present invention.
14 is a conceptual view for explaining a method for manufacturing a vein injection simulator according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

Prior to the description of the present invention, the following specific structures or functional descriptions are merely illustrated for the purpose of describing embodiments according to the inventive concept, and the embodiments according to the inventive concept may be implemented in various forms, It should not be construed as limited to the embodiments described herein.

In addition, embodiments in accordance with the concepts of the present invention may be modified in various ways and may have various forms, specific embodiments will be illustrated in the drawings and described in detail herein. However, this is not intended to limit the embodiments in accordance with the concept of the present invention to a particular disclosed form, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

The present invention relates to a simulator 10 that can practice intravenous injection by being fixed to an extremity such as an arm or a leg, and can practice an injection that can feel an injection reaction force similar to that of an actual human extremity. When the tourniquet (C) is tied up, it is possible to realistically simulate the phenomenon of expansion of a blood vessel of a person, which is characterized by a more realistic injection practice. In addition, the simulator 10 can be used as a fixed mannequin for training as well as a person's limbs. The arm of the training mannequin itself may be implemented by the present invention.

The following description will be based on the form of fixing to the limbs of a person.

Simulator 10 according to the present invention to implement the above features largely comprises a casing 100, elastic pad 200, vessel tube 300 and pressure plate 400 as shown in Figs. do.

In this case, the casing 100 is attached to a box shape in which an upper surface is opened and an accommodation space 110 is formed inward to accommodate the elastic pad 200, the blood vessel tube 300, and the pressure plate 400 to be described later. Although illustrated as a substantially rectangular box shape, it is not limited thereto, and it may be found that the present invention may be modified in various shapes. In addition, as shown in FIGS. 1 and 2, the cross section of the casing 100 may be bent into an approximately arc-shaped shape, which is closer to the limb when the simulator 10 is fixed to the surface of the curved limb. To make it possible.

In addition, the left and right ends of the casing 100, the band mounting piece 120 may be formed integrally, and after connecting the rear end of the band to the band mounting piece 120, a coupling means such as a velcro is attached to the front end of the band. It is also possible to employ the simulator 10 to be fixed to the limbs. In addition, the left and right sides of the casing 100 is formed through the side opening 130 so that the tourniquet C can press both sides of the elastic pad 200 when the tourniquet C is bundled. The operation of the tourniquet C and the side opening 130 will be described later.

On the other hand, as shown in Figure 2, one side of the casing 100, the discharge hole 140 is formed so that the end of the blood vessel tube 300 to be described later is formed and also the periphery of the open upper surface of the casing 100 A stepped locking step 150 may be formed toward the inner side of the casing 100, and the locking step 150 may include an elastic pad 200 accommodated in the storage space 110 of the casing 100. At 110, it acts to prevent the departure by its own weight.

In addition, the lower surface of the casing 100 is provided with a pair of hinges 160 to which the pivot pin 411 of the intermediate plate 410 to be described later is connected and at the same time to allow the lever operation of the pressure plate 400. The opening 170 is formed through. That is, the pivot pin 411 is rotatably connected to the hinge 160 so that the pressure plate 400 to be described later is rotatable while closing the bottom opening 170 of the casing 100.

Next, the vascular tube 300 is bent in a substantially 'U' shape in the form of a tube flowing simulated blood, is interposed on the elastic pad 200 to be described later.

The simulated blood flowing through the blood vessel tube 300 corresponds to the distilled water corresponding to the plasma in the blood to simulate the actual blood, the red ink and the black ink used to control the degree of red and black of the blood, and the cholesterol in the blood. As a result, a gel component showing the viscosity of the blood is mixed and formed. Specifically, the simulated blood is preferably formed by mixing 3 to 80% by weight of red ink, 3 to 80% by weight of black ink and 3 to 30% by weight of gel component with respect to 100% by weight of distilled water. It is more preferable that the sum total of black ink is 80 to 85 weight%.

Next, the elastic pad 200 is accommodated in the housing space 110 of the casing 100, it is preferable that the elastic deformation is made of an elastic material, for example, silicone or rubber material to be flexible to resemble a human skin. That is, the pad member corresponding to each layer may be superimposed so as to resemble the texture of the epidermal layer, dermis layer, subcutaneous fat layer, muscle layer, etc. constituting real human skin, but in this embodiment, the dermis and the epidermis are respectively simulated. The elastic pad 200 composed of the dermal layer 220 and the epidermal layer 210 will be described. In addition, although the shape of the elastic pad 200 is illustrated in a quadrangular shape as shown in FIGS. 2 to 3, when the elastic deformation is accommodated in the storage space 110 of the casing 100, the storage space 110 and Of course, the elastic deformation in the corresponding shape.

Meanwhile, the elastic pad 200 is divided into a dermal layer 220 and an epidermal layer 210 which are detached from each other. More specifically, the dermal layer 220 of the elastic pad 200 is a portion corresponding to the human dermis, and the tube holder 221 in which the vascular tube 300 is seated on the upper surface is recessed and the hinge stand of the casing 100 is lowered. The reinforcing rib 440 of the pressure plate 400 and the pressure plate 400 to be described later and a plurality of receiving grooves 222 corresponding to angles of the pressure protrusion are formed. That is, the receiving groove 222 is to prevent the dermis layer 220 from interfering with the pressure plate 400 to be received in the receiving space 110.

Next, the pressure plate 400 is rotatably installed on the lower surface of the casing 100 and acts to press the lower surface of the elastic pad 200 and the blood vessel tube 300 while being rotated. More specifically, the pressure plate 400 installed to cover the lower surface opening 170 and rotated to be approximately the same as the principle of the lever is an intermediate plate 410, a lower plate (shown in Figures 1 to 3). The 420 and the rising plate 430 are integrally formed. At this time, the operation of the intermediate plate 410, the lower plate 420 and the rising plate 430 will be described briefly, the pressure plate 400 is in the shape of a lever, the intermediate plate 410 constituting it is a support point of the lever The lower plate 420 corresponds to the force point of the lever, and the rising plate 430 corresponds to the action point of the lever.

On the other hand, the intermediate plate 410 is provided with a pivot pin 411 on both sides of the left and right pivot pin 411 acts as a supporting point. At this time, the pivot pin 411 is connected to the hinge 160 described above in a substantially cylindrical shape so that the pressure plate 400 rotates about the pivot pin 411 and the hinge table 160 as a center point. Next, the lower plate 420 is attached to one side of the intermediate plate 410 to receive the pressure of the elastic pad 200 to act as a force point and the rising plate 430 is attached to the other side of the intermediate plate 410 pressure This acts as a working point of the falling plate 420 is delivered.

That is, the pressure plate 400 operates in the direction of the arrow shown in FIG. 5B when an external force is received in the direction of the arrow shown in FIG. 5A. Specific working examples of the pressure plate 400 will be described later.

In addition, a reinforcing rib 440 for strength reinforcement may be formed on the outer surface of the pressure plate 400, and the elastic pad 200 is pressed on the upper surface of the rising plate 430 as shown in FIG. 2. Reinforcing protrusions 431 may be further formed to add a force.

Hereinafter, with reference to the accompanying drawings will be described an operation example of the intravenous injection simulator 10 according to the present invention.

First, the lower surface of the casing 100, ie, the pressure plate 400 and the casing 100 in which the elastic pad 200 and the blood vessel tube 300 are accommodated are fixed to the limbs as shown in FIG. 13A. Then, the tourniquet C is tied to one side of the simulator 10 as shown in FIG. 13B. At this time, the tourniquet (C) may be used, such as cloth, elastic band, the user is tied to the upper portion of about 10 ~ 12cm at the position to inject the needle so that the limb and the simulator 10 can be fixed at the same time. In this embodiment, by tying the tourniquet C in a direction in which the side opening 130 of the casing 100 is formed, both the upper and left and right sides of the elastic pad 200 are pressed by the tourniquet C. It is configured to be.

When the tourniquet (C) is bound as described above, as shown in FIG. 5B, the elastic pad 200 is pressed while the pressure plate 400 performs the lever movement. That is, as the lowering plate 420 descends and the rising plate 430 is raised, the dermal layer 220 of the elastic pad 200 is elastically deformed, and accordingly, the expanded portion 322 of the scanning unit 320 is illustrated. Inflate as visually as shown in 12b and 13b.

In other words, when the tourniquet C is tied to one side of the simulator 10, one side of the elastic pad 200 is pressed and the lower plate 420 acts as a force point, while the rising plate 430 acts as an action point. The pad 200 and the blood vessel tube 300 are simultaneously pushed upward to expand the blood vessel tube 300.

Therefore, the user can not only practice intravenous injection on the simulator 10 but also visually confirm that the blood vessel tube 300 is expanded when the tourniquet C is used, so that the user can proceed with more realistic practice. .

Hereinafter, another embodiment of the simulator according to the present invention will be described. The same or similar parts as described above will be omitted in order to avoid duplication. In order to implement the above characteristics, the simulator 10 according to another embodiment of the present invention has a casing 100, an elastic pad 200, a blood vessel tube 300, and a pressure plate 400 as shown in FIGS. 6 to 8. It is configured to include.

At this time, the blood vessel tube 300 is formed in a shape bent approximately 'U' so that the injection unit 320 and the compression unit 310 are configured to communicate with each other in a unitary shape different from each other in the upper and lower heights in the form of a simulated blood flow. More specifically, the injection unit 320 is interposed on the elastic pad 200, which will be described later, and the needle is directly injected into the injection path may be formed in the heavy water pipe 321 corresponding to the human mesenteric vein.

In addition, the pressing unit 310 extends from the scanning unit 320 and positioned in parallel with each other, but located below the scanning unit 320. More specifically, as illustrated in FIG. 10, the injection unit 320 in which the needle is injected is configured to be located above the compression unit 310 and the injection unit 310 in which the needle is not directly injected. ) May be located below the scanning unit 320 relatively.

In addition, as shown in Figure 9, the blood vessel tube 300 is configured to be alternately installed in the left and right, left and right width direction alternately connected to each other. That is, the present embodiment has described an example in which two blood vessel tubes 300 are integrally formed, and when each blood vessel tube 300 is connected to each other, it may be configured to communicate with each other by a connection pipe 330. At this time, of course, the connecting tube 330 and each of the blood vessel tubes 300 may be formed integrally. In addition, in order to mimic the blood vessels of humans, the diameters of the respective vascular tubes 300 may be configured differently from each other.

When the tourniquet is configured as described above, when the tourniquet is tied to one side of the simulator 10, one side of the elastic pad 200 is pressed while the lowering plate 420 acts as a force point, and at the same time, the rising plate 430 acts. While acting as an elastic pad 200 and the vascular tube 300 at the same time to the upper to expand the vascular tube 300, more specifically the injection unit 320 to the upper.

On the other hand, in order to continuously supply the simulated blood to the blood vessel tube 300 may be provided with a pump (P) connected to the blood vessel tube 300, as shown in Figure 9, the pump (P) is a known feed pump In some cases, a blood storage tank in which the simulated blood is stored is connected to the pump P, so that the simulated blood of the blood storage tank circulates the blood vessel tube 300. In addition, the pump (P) may be implemented integrally with the simulator 10, of course.

Accordingly, the simulated blood flowing in the blood vessel tube 300 according to the present invention always flows in the same direction in the blood vessel tube 300. Specifically, as illustrated in FIG. 10, the heights of the injection unit 320 and the compression unit 310 are different from each other, so that the needles are injected into the injection unit 320 as shown in FIG. 9. By expressing the flow direction of the simulated blood to flow in only one direction, the flow direction of the simulated blood can be configured to be similar to the flow direction of the blood flowing in the blood vessels of a real person. The user can be provided with a more realistic simulator (10).

Next, the elastic pad 200 is divided into a dermal layer 220 and an epidermal layer 210 which are detached from each other. More specifically, the dermal layer 220 of the elastic pad 200 is a portion corresponding to the human dermis, and the tube holder 221 in which the vascular tube 300 is seated on the upper surface is recessed and the hinge stand of the casing 100 is lowered. The reinforcing rib 440 of the pressure plate 400 and the pressure plate 400 to be described later and a plurality of receiving grooves 222 corresponding to angles of the pressure protrusion are formed. That is, the receiving groove 222 is to prevent the dermis layer 220 from interfering with the pressure plate 400 to be received in the receiving space 110.

More specifically, the tube fixture 221 communicates with the first buried portion 221-1 and the first buried portion 221-1 in which the pressing portion 310 of the blood vessel tube 300, which will be described later, is completely embedded. A portion of the lower surface of the injection unit 320 of the blood vessel tube 300 to be described later is composed of a second buried portion (221-2). In other words, the tube fixture 221 is configured to have the same shape as the blood vessel tube 300, but by configuring the vertical height of the first buried portion 221-1 and the second buried portion 221-2 different from each other As shown in FIG. 10, the upper and lower heights may be accommodated in the scanning part 320 and the pressing part 310, and the second buried part 221-2 may be part of the lower surface of the scanning part 320. By accommodating the portion of the upper surface of the scanning unit 320 can be exposed so that the epidermal layer 210, which will be described later, functions to accommodate a portion of the upper surface of the scanning unit 320.

In addition, since the needle is not directly injected into the dermal layer 220, it is preferable that the injection molding is made of transparent silicone having a shore diameter of 10 to 20A.

In addition, the epidermal layer 210 may cover the upper surface of the dermal layer 220 and have a lower hardness than the dermal layer 220. For example, since the epidermal layer 210 needs to be simulated similar to human skin, it is preferable that the epidermal layer 210 is formed of natural hardening silicone having a Shore hardness of 1 to 5 A so as to resemble a human skin texture.

In addition, the epidermal layer 210 has a third buried portion 211 that receives a portion of the upper surface of the scanning portion 320 is recessed upward. In this case, the epidermal layer 210 is configured to accommodate the upper surface of the scanning unit 320 opened as shown in FIG. 10 and prevents the injection unit 320 from being exposed to the outside and simultaneously scans the needle. It is desirable to form an appropriate thickness so as to resemble the sensitivity to inject into the actual skin when injecting into the portion 320.

Meanwhile, the epidermal layer 210 directly corresponds to the epidermis of the skin, and a low hardness silicone is used as the main material. In the case of the low hardness silicone to realistically express the texture of the skin, it is generally expensive. In other words, if the kit is manufactured using a large amount of low hardness silicone, the manufacturing cost increases.

However, the simulator 10 according to the present invention separately divides the elastic pad 200 into the epidermal layer 210 and the dermis layer 220, respectively, and the upper surface of the injection unit 320 of the blood vessel tube 300 in which the actual needle is injected. By allowing the silicon (epidermal layer 210) of low hardness to be located only in the part corresponding to the user, while reducing the manufacturing cost of the simulator 10, the user can realistically proceed to the intravenous injection practice for improving the skill.

Hereinafter, a manufacturing method of the intravenous injection simulator 10 according to the present invention will be described with reference to the accompanying drawings. In this case, the meaning of the terms used will not be described in detail to avoid duplication with the above description.

First, as illustrated in FIG. 14A, silicon is injection molded to form the dermal layer 220. At this time, since the dermis layer 220 is a portion where the needle is not directly injected, it is possible to use silicon having a relatively high Shore hardness. Accordingly, injection molding through a mold is possible. That is, it is possible to form a large amount of dermal layer 220 in a short time.

Next, as shown in FIG. 14B, the silicon is naturally hardened to form the epidermal layer 210 having a lower hardness than the dermal layer 220. At this time, since the epidermal layer 210 is a portion where the needle is directly injected, silicon having a low Shore hardness is used to express a texture similar to a real human skin. Silicon of low hardness cannot be injection molded through a mold and is manufactured by natural curing at room temperature through a mold for preparing the epidermal layer 210.

On the other hand, since the natural curing silicone used for the manufacture of the epidermal layer 210 is relatively expensive, the manufacturing cost can be lowered by using the natural curing silicone only in the epidermal layer 210 to which the needle is directly injected. In addition, by injection molding the dermal layer 220 it is possible to take advantage of the mass production is possible at the same time.

Next, as illustrated in FIG. 14C, the blood vessel tube 300 may be provided on the elastic pad 200 having the vascular tube 300 through which simulated blood flows, and as shown in FIG. 14D, wherein the dermal layer 220 and the epidermal layer 210 are combined. After the 300 is inserted into the casing 100 made of synthetic resin injection molding to produce a simulator (10).

10: simulator
100: casing
110: storage space
120: band installation
130: side opening
140: discharge hole
150: jamming jaw
160: hinge
170: bottom opening
200: elastic pad
210: epidermal layer
220: dermal layer
221: tube fixture
221-1: first landfill
221-2: second buried portion
222: receiving home
300: blood vessel tube
310: pressure portion
320: scanning unit
400: pressure plate
410: middle plate
420: descent plate
430 rising plate
440: reinforcement rib

Claims (5)

Elastic pads of elastic material;
A blood vessel tube interposed on the elastic pad in a tube shape in which simulated blood flows; And
The pressure plate is rotatably installed on the lower surface of the casing;
The pressure plate rotates and compresses the lower surface of the elastic pad and the blood vessel tube,
The pressure plate is in the shape of a lever,
Intermediate plate is installed on the left and right sides of the pivot pin acts as a support point;
A lower plate attached to one side of the intermediate plate to receive a pressure of an elastic pad and act as a force point; And
When the tourniquet is tied to one side of the simulator including a rising plate that is attached to the other side of the intermediate plate and acts as a functioning point of the lowering plate to which pressure is transmitted, one side of the elastic pad is pressed while the lowering plate acts as a force point. Intravenous injection simulator that can act as a functioning point to expand the vascular tube by simultaneously pressing the elastic pad and the vascular tube to expand the vascular tube. delete The method according to claim 1,
The upper surface is opened and the casing formed a receiving space inward; further comprising,
The casing is an intravenous simulator that can implement vasodilation, characterized in that fixed to at least one of the limbs and mannequins. delete delete

Images