JP6757483B1 - Thoracic simulator stand - Google Patents

Abstract

Provided is a stand for the thoracic cavity simulator that can easily support the thoracic cavity simulator in the lateral decubitus position and can adjust the lateral decubitus position by rotating the thoracic cavity simulator with the vertical direction of the thoracic cavity simulator as the rotation axis direction. To do. A stand that supports the thoracic cavity simulator in the lateral decubitus position, connecting the upper end support member that supports the upper end side wall of the thoracic cavity simulator, the lower end support member that supports the lower end side wall of the thoracic cavity simulator, and the upper end support member and the lower end support member. The upper end support member is provided with an upper end concave gap between the first and second upper end side wall support portions and the two upper end side wall support portions, and the lower end support member is a first and second upper end side wall support portion. A lower end concave gap is provided between the lower end side wall support and the two lower end side wall supports, and each of the first and second upper end side wall supports abuts on the upper end side wall of the thoracic cavity simulator, and the first and first Each of the lower end side wall supports of 2 may come into contact with the lower end side wall of the thoracic cavity simulator.

Description

The present invention relates to an instrument that supports a thoracic cavity simulator for training and learning of video-assisted thoracoscopic surgery.

In recent years, for training and learning of video-assisted thoracoscopic surgery, a simulator has been developed that can reproduce a human body shape and texture and simulate a surgical environment for a human body (see, for example, Patent Document 1).
The thoracic cavity simulator disclosed in Patent Document 1 is a device including at least a human skeleton model simulating a rib and a casing for accommodating the human skeleton model, and an opening is provided in the rib portion of the casing to provide a diaphragm. The part can be opened and closed, and the organ model can be stored inside the ribs of the human skeleton model. According to this, it is possible to effectively perform video-assisted thoracoscopic surgery procedure training.
Since the thoracic cavity simulator disclosed in Patent Document 1 is premised on training in the supine position, the mechanism for tilting and fixing the thoracic cavity simulator to the left and right is not disclosed, but the target site for surgery and the target site for surgery Since there are cases where surgery is performed in the lateral decubitus position depending on the surgical procedure, an instrument that can support the thoracic cavity simulator at an appropriate angle is desired when performing surgery in the lateral decubitus position.

As a technology that enables the angle adjustment of the simulator, the angle can be adjusted by configuring the top cover of the trainer to make an angle with respect to the base and the entire trainer to make an angle with respect to the top plate of the table. Surgical training devices are known (see Patent Document 2).
In the surgical training device disclosed in Patent Document 2, a technique for tilting the training device forward or backward is disclosed, and the training device may be formed so as to be tilted laterally. There is not enough disclosure about how to tilt the trainer to the side.

Further, there is known a training organ installation device provided with polygonal legs that can rotate the main body (see Patent Document 3). This is because polygonal legs are provided at both ends of the main body of the training organ installation device, and by rotating the main body, the same environment as rotating the patient's body position can be reproduced.
However, in the training organ setting device disclosed in Patent Document 3, an octagonal leg is shown as a polygonal leg in the examples, but it is said that fine adjustment of the angle is difficult with this. There's a problem. Further, if the configuration has more corners in order to enable fine adjustment, there is a problem that the stability of the ground contact portion is impaired.

International pamphlet WO2015 / 151503 JP-A-2017-201416 Utility Model Registration No. 3177527

In view of such a situation, the present invention can easily support the thoracic cavity simulator in the lateral decubitus position, and the thoracic cavity simulator is rotated with the vertical direction of the thoracic cavity simulator as the rotation axis direction to be in the lateral decubitus position. It is an object of the present invention to provide a stand for a thoracic cavity simulator capable of adjusting the posture.

In order to solve the above problems, the thoracic cavity simulator stand of the present invention is a stand that supports the thoracic cavity simulator in a lateral decubitus position, and has an upper end support member that supports the upper end side wall of the thoracic cavity simulator and a lower end side wall of the thoracic cavity simulator. It consists of a lower end support member to support and a connecting member connecting the upper end support member and the lower end support member, and the upper end support member has an upper end concave gap between the first and second upper end side wall support portions and the two upper end side wall support portions. The lower end support member is provided with a lower end concave gap between the first and second lower end side wall support portions and the two lower end side wall support portions, and the first and second upper end side wall support portions thereof. Each may come into contact with the upper side wall of the thoracic cavity simulator, and each of the first and second lower end side wall supports may come into contact with the lower end side wall of the thoracic cavity simulator.
The thoracic cavity simulator can be stably supported by abutting the first and second upper end side wall support portions and the first and second lower end side wall support portions at a total of four locations. Further, by providing the upper end concave gap and the lower end concave gap, for example, even if the tip of the upper end side wall of the thoracic cavity simulator is provided thinly, the protrusion can be absorbed by the upper end concave gap, and the thoracic cavity simulator is firmly supported. Can be done.
As for the installation direction of the thoracic cavity simulator, it can be supported by either left or right up and down, so it is possible to perform training to operate the right lung, for example, or to perform training to operate the left lung using one stand. You can also.

In the thoracic cavity simulator stand of the present invention, it is preferable and more preferable that the thoracic cavity simulator can be rotated in the range of -20 to 20 ° with the vertical direction of the thoracic cavity simulator as the rotation axis direction to adjust the lateral decubitus position. Is -15 to 15 °.
This is because the thoracic cavity simulator stand can be stably supported in the range of -20 to 20 °, and the needs for procedural training can be met if the state posture can be adjusted in such a range.

In the thoracic cavity simulator stand of the present invention, the contact of the first and second upper end side wall support portions with the upper end side wall of each thoracic cavity simulator and the thoracic cavity simulators of the first and second lower end side wall support portions. The contact with the lower end side wall of the above may be surface contact or line contact, but at least one of the above contact is preferably point contact.
By making the contact points point-to-point contact, it becomes easy to adjust the posture in the lateral decubitus position.

In the thoracic cavity simulator stand of the present invention, it is preferable that at least one of the upper end support member and the lower end support member is provided with a guide wall for positioning the installation position of the upper end or the lower end of the thoracic cavity simulator.
By providing the guide wall, the thoracic cavity simulator is naturally installed inside the guide wall at the time of installation, so that the installation position of the upper end or the lower end of the thoracic cavity simulator can be easily positioned. Therefore, it is preferable to provide it on both the upper end support member and the lower end support member.

The thoracic cavity simulator stand of the present invention preferably has a non-slip mechanism provided at least on either the upper end side wall support portion or the lower end side wall support portion.
By providing the non-slip mechanism, the thoracic cavity simulator can be supported more stably. As the non-slip mechanism, a member made of a resin material is preferably used, but a hook-and-loop fastener or the like may be used.

In the thoracic cavity simulator stand of the present invention, it is preferable that the connecting member is detachable from at least one of the upper end support member and the lower end support member, and can be folded by a hinge mechanism provided in the middle portion in the longitudinal direction.
Since it can be disassembled and folded, it can be stored compactly when not in use and has a structure that is easy to carry.

In the thoracic cavity simulator stand of the present invention, the upper end support member, the lower end support member, and the connecting member may be integrated.
By integrating the upper end support member, the lower end support member, and the connecting member, the strength of the thoracic cavity simulator stand can be increased.

The thoracic cavity simulator stand of the present invention may be provided with a guide marker for adjusting the angle of the lateral decubitus position of the thoracic cavity simulator on at least one of the upper end support member and the lower end support member.
The provision of the guide marker facilitates the angle adjustment of the thoracic cavity simulator. Therefore, the marker provided on the thoracic cavity simulator stand may be aligned with reference to a specific part of the thoracic cavity simulator. Further, the guide marker may be provided in the thoracic cavity simulator as well as the guide marker provided in the thoracic cavity simulator stand.

The thoracic cavity simulator stand of the present invention is further provided with a rotation mechanism capable of rotating the upper end support member, the lower end support member, and the connecting member without changing the support position of the thoracic cavity simulator with the vertical direction of the thoracic cavity simulator as the rotation axis direction. It may have been done.
By providing the rotation mechanism, for example, it is possible to finely adjust the angle by the rotation mechanism after adjusting the angle by a human hand. In addition, it becomes easy to adjust the angle during the procedure training.

In the thoracic cavity simulator stand of the present invention, the upper end support member and the lower end support member have a rotation mechanism capable of rotating the thoracic cavity simulator itself without changing the support position of the thoracic cavity simulator with the vertical direction of the thoracic cavity simulator as the rotation axis direction. It may be further provided.
By providing the rotation mechanism on the upper end support member and the lower end support member, the thoracic cavity simulator itself can be rotated while the connecting member is fixed.

According to the thoracic cavity simulator stand of the present invention, the thoracic cavity simulator can be easily supported in the lateral decubitus position, and the thoracic cavity simulator is rotated with the vertical direction of the thoracic cavity simulator as the rotation axis direction to perform the lateral decubitus position. It has the effect of being able to adjust the state posture.

Perspective view of the stand for the thoracic cavity simulator of Example 1 External view 1 of the stand for the thoracic cavity simulator of Example 1 External view 2 of the stand for the thoracic cavity simulator of Example 1 External view 3 of the stand for the thoracic cavity simulator of Example 1 Disassembly and assembly explanatory view of the stand for the thoracic cavity simulator of Example 1 Assembly explanatory view of the stand for the thoracic cavity simulator of Example 1 Use flow chart of the stand for the thoracic cavity simulator of Example 1 Perspective view showing the usage state of the thoracic cavity simulator stand of Example 1. External view 1 showing the usage state of the thoracic cavity simulator stand of Example 1. External view 2 showing the usage state of the thoracic cavity simulator stand of Example 1. External view 3 showing a usage state of the thoracic cavity simulator stand of Example 1. Explanatory drawing of angle adjustment Perspective view showing the usage state of the thoracic cavity simulator stand of Example 2. Perspective view of the stand for the thoracic cavity simulator of Example 3 External view of the stand for the thoracic cavity simulator of Example 3 Perspective view showing the usage state of the thoracic cavity simulator stand of Example 3. Use flow chart of the stand for the thoracic cavity simulator of Example 3 Thoracic simulator perspective view External view of thoracic cavity simulator 1 External view of the thoracic cavity simulator 2 External view of thoracic cavity simulator 3

Hereinafter, an example of the embodiment of the present invention will be described in detail with reference to the drawings. The scope of the present invention is not limited to the following examples and illustrated examples, and many modifications and modifications can be made.

First, the structure of the thoracic cavity simulator attached to the thoracic cavity simulator stand will be described. FIG. 18 shows a perspective view of the thoracic cavity simulator. 19 to 21 are external views of the thoracic cavity simulator, FIG. 19 (1) is a front view, FIG. 19 (2) is a rear view, FIG. 20 (1) is a right side view, and FIG. 20 (2) is a right side view. The left side view, FIG. 21 (1) is a plan view, and FIG. 21 (2) is a bottom view.
As shown in FIG. 18, the thoracic cavity simulator 9 includes an upper end portion 91, a lower end portion 92, a sternum portion 93, a spine portion 94, and a rib portion 95. An upper end 91 is provided at the upper ends of the sternum 93 and the spine 94, and a lower end 92 is provided at the lower ends. The rib portion 95 is fixed to the sternum portion 93 and the spine portion 94. Further, as shown in FIG. 21 (2), the lower end portion 92 is provided with a through hole 96 for attaching an organ model (not shown). As described above, the thoracic cavity simulator 9 has a shape simulating the chest of the human body.

When the thoracic cavity simulator 9 is used in the supine position, the spine portion 94 is installed so as to come into contact with the installation table or the like. As shown in FIG. 21 (2), since the side wall 91c on the back side of the upper end 91 has a substantially linear shape, when the thoracic cavity simulator 9 is installed in the supine position on an installation table or the like, a special fixture or the like is used. Even if it is not used, it can be placed stably and the procedure training can be performed.
However, when performing lung surgery, the surgery is often performed in the lateral decubitus position, and depending on the surgical procedure, the right side portion 9a and the left side portion 9b shown in FIGS. 19 (1) and 19 (2) are downward. It is necessary to install the thoracic cavity simulator 9 so as to be.
However, as shown in FIG. 21 (1), both the right side wall 91a and the left side wall 91b of the upper end portion 91 of the thoracic cavity simulator 9 have a curved surface shape. Further, as shown in FIG. 21 (2), the lower end portion 92 of the thoracic cavity simulator 9 also has a curved surface shape on both the right side wall 92a and the left side wall 92b. Therefore, it is difficult to install the thoracic cavity simulator 9 sideways without using a fixed base or the like. Therefore, a stand that stably supports the upper end portion 91 and the lower end portion 92 having a curved surface shape is required. Further, the lateral decubitus position is not always required to be fixed at an angle of 90 ° with respect to the supine position, and depending on the content of the training, it may be desirable to install it with a slight inclination. Therefore, a stand that fixes the thoracic cavity simulator 9 sideways and can adjust the angle is required.
In the thoracic cavity simulator 9, the right side portion 9a and the left side portion 9b are used, but the left and right sides are assumed to be along the left and right sides in the structure of the human body. That is, the right hand side is the right side portion 9a, and the left hand side is the left side portion 9b.

Next, the structure of the thoracic cavity simulator stand will be described. FIG. 1 shows an external perspective view of the stand for a thoracic cavity simulator according to the first embodiment. 2 to 4 are external views of the thoracic cavity simulator stand, FIG. 2 (1) is a front view, FIG. 2 (2) is a rear view, and FIG. 3 (1) is a right side view and FIG. 3 (2). ) Is a left side view, FIG. 4 (1) is a plan view, and FIG. 4 (2) is a bottom view.
As shown in FIG. 1, the thoracic cavity simulator stand 1 is composed of an upper end support member 2, a lower end support member 3, and a connecting member 4.
The upper end support member 2 is provided with an upper end side wall support portion (21, 22) and a guide wall 24. The upper end side wall support portion 21 is provided with a non-slip mechanism 6a using a resin member in order to facilitate supporting the upper end portion 91 of the thoracic cavity simulator 9. Similarly, the upper end side wall support portion 22 is provided with a non-slip mechanism 6b. A gap 23 is provided between the upper end side wall support portion 21 and the upper end side wall support portion 22. By providing the gap portion 23, even if the tip of the side wall of the upper end portion 91 of the thoracic cavity simulator 9 is provided thinly, the protrusion can be absorbed by the gap portion 23 and firmly at the upper end side wall support portion (21, 22). It is possible to support. Further, even when the angle of the thoracic cavity simulator 9 to be installed is changed, point contact can be easily made at the upper end side wall support portions (21, 22).

The lower end support member 3 is provided with lower end side wall support portions (31, 32) and a guide wall 34. Similar to the upper end side wall support portions (21, 22), the lower end side wall support portions (31, 32) are also provided with anti-slip mechanisms (6c, 6d) in order to easily support the lower end portion 92 of the thoracic cavity simulator 9. ing. Further, a gap 33 is also provided between the lower end side wall support portion 31 and the lower end side wall support portion 32, and the lower end side wall support portions (31, 32) can be easily provided even when the angle of the thoracic cavity simulator 9 to be installed is changed. ) Has a structure that allows point contact.
The guide wall 24 provided on the upper end support member 2 and the guide wall 34 provided on the lower end support member 3 facilitate positioning of the thoracic cavity simulator stand 1 in the front-rear direction, that is, in the vertical direction of the thoracic cavity simulator 9. It is provided in.

The connecting member 4 is composed of a connecting part 4a and a connecting part 4b, and the connecting part 4a and the connecting part 4b are connected by a hinge 5. As shown in FIGS. 3 (1) and 3 (2), the connecting parts (4a and 4b) are provided with through holes 41 for the purpose of reducing the weight.

5A and 5B are exploded and assembled explanatory views of the thoracic cavity simulator stand of the first embodiment, FIG. 5 (1) shows an explanatory view of each member, and FIG. 5 (2) shows an explanatory view of a connecting member.
The thoracic cavity simulator stand 1 shown in FIGS. 1 to 4 can be disassembled and stored compactly when not in use. That is, as shown in FIG. 5 (1), the thoracic cavity simulator stand 1 can be disassembled into three parts: an upper end support member 2, a lower end support member 3, and a connecting member 4. Further, as shown in FIG. 5 (2), the connecting member 4 can be folded and stored by the hinge 5.

FIG. 6 is an assembly explanatory view of the thoracic cavity simulator stand of the first embodiment. As shown in FIG. 6, the lower end support member 3 is provided with a convex portion 35. Further, the connecting part 4b is provided with a concave portion 42b, and the convex portion 35 and the concave portion 42b can be fitted and fixed. Although not shown here, the convex portion 25 provided on the upper end support member 2 and the concave portion 42a provided on the connecting part 4a shown in FIG. 5 (1) have the same structure.

FIG. 7 shows a usage flow chart of the thoracic cavity simulator stand of Example 1. As shown in FIG. 7, when using the thoracic cavity simulator stand 1, first, an organ model (not shown) is installed in the thoracic cavity simulator 9 (step S01).
Next, the folded connecting member 4 as shown in FIG. 5 (2) is extended as shown in FIG. 5 (1) (step S02). The upper end support member 2 and the lower end support member 3 are attached to the extended connecting member 4 (step S03). Specifically, the concave portion 42a provided in the connecting part 4a and the convex portion 25 provided in the upper end support member 2 are fitted and fixed. Similarly, the concave portion 42b provided in the connecting part 4b and the convex portion 35 provided in the lower end support member 3 are fitted and fixed.
The thoracic cavity simulator 9 is installed on the assembled thoracic cavity simulator stand 1 (step S04). Since the installation is performed by placing the thoracic cavity simulator 9 on the thoracic cavity simulator stand 1, it is possible to finely adjust the installation angle by human hands.
It should be noted that the installation of the organ model in step S01 does not necessarily have to be performed first, and for example, it can be performed after step S04 in which the thoracic cavity simulator 9 is installed on the thoracic cavity simulator stand 1.

Next, a state in which the thoracic cavity simulator 9 is attached to the thoracic cavity simulator stand 1 will be described. FIG. 8 is a perspective view showing a usage state of the thoracic cavity simulator stand of Example 1. 9 to 11 are external views showing a usage state of the thoracic cavity simulator stand of the first embodiment, FIG. 9 (1) is a front view, FIG. 9 (2) is a rear view, and FIG. 10 (1) is a rear view. A right side view, FIG. 10 (2) is a left side view, FIG. 11 (1) is a plan view, and FIG. 11 (2) is a bottom view.
As shown in FIG. 8, in this embodiment, a case of training related to right lung surgery is shown, and a thoracic cavity simulator stand is provided so that the right side portion 9a of the thoracic cavity simulator 9 is on the upper side and the left side portion 9b is on the lower side. It is installed in 1. Specifically, as shown in FIGS. 10 (1) and 10 (2), the left side wall 91b of the upper end portion 91 is supported by the upper end side wall support portions (21, 22), and the left side wall 92b of the lower end portion 92 is the lower end. It is supported by the side wall support portions (31, 32).

As shown in FIGS. 9 (1) and 9 (2), the thoracic cavity simulator 9 is installed so that the right side portion 9a is on the upper side and the left side portion 9b is on the lower side, but depending on the content of the procedure training, the thoracic cavity simulator 9 is installed. It is also possible to install the 9 at an angle. 12A and 12B are explanatory views of angle adjustment, where (1) is tilted to the left and (2) is tilted to the right.
As shown in FIGS. 1 and 4, the upper end side wall support portions (21, 22) and the lower end side wall support portions (31, 32) of the thoracic cavity simulator stand 1 are provided with anti-slip mechanisms (6a to 6d). Moreover, since the gaps (23, 33) are provided, when the thoracic cavity simulator 9 is installed, point contact is made at four points of the non-slip mechanism (6a to 6d). As a result, it is possible to install the product with an inclination as shown in FIG.
The angle R ₁ in FIG. 12 (1) is 15 °, and the angle R ₂ in FIG. 12 (2) is also 15 °. Here, the thoracic cavity simulator stand 1 is tilted by 15 ° to the left and right, but the thoracic cavity simulator 9 is configured to be tilted by 20 ° to the left and right.

FIG. 13 is a perspective view showing a usage state of the thoracic cavity simulator stand of the second embodiment. As shown in FIG. 13, a guide marker 8a is provided on the lower end support member 3 of the thoracic cavity simulator stand 10. Further, also in the thoracic cavity simulator 9, a guide marker 8b is provided on the inner wall of the lower end portion 92.
By providing the guide marker 8a and the guide marker 8b, positioning can be performed with reference to the positions of the guide marker 8a and the guide marker 8b, so that the installation angle of the thoracic cavity simulator 9 can be easily adjusted. Although only two markers are shown here, for example, a marker may be provided on the upper end support member 2 and the upper end 91 of the thoracic cavity simulator 9.
The thoracic cavity simulator stand 10 is the same as the thoracic cavity simulator stand 1 except that the guide marker 8a is provided.

In the thoracic cavity simulator stand 1 according to the first embodiment, the installation angle is manually adjusted. Therefore, for example, if it is desired to tilt the thoracic cavity simulator 9 to the left by 1 ° after installing it once, the installed thoracic cavity simulator 9 is lifted and re-installed. However, there is a problem that fine adjustment by human hands tends to cause an error. Therefore, a configuration that allows fine adjustment after manual installation will be described.
FIG. 14 shows a perspective view of the thoracic cavity simulator stand of Example 3. As shown in FIG. 14, the thoracic cavity simulator stand 11 includes an upper end support member 20, a lower end support member 30, and a connecting member 4.
The upper end support member 20 is composed of a support portion 20a and a rotating portion 20b, and the rotating portion 20b is provided with an upper end side wall support portion (21, 22) and a guide wall 24. Similar to the first embodiment, the upper end side wall support portions (21, 22) are provided with anti-slip mechanisms (6a, 6b) using resin members in order to easily support the upper end portion 91 of the thoracic cavity simulator 9. It is provided. The same as in the first embodiment, the point that the gap portion 23 is provided between the upper end side wall support portion 21 and the upper end side wall support portion 22 and the point that the positioning guide wall 24 is provided.
Further, the lower end support member 30 is composed of a support portion 30a and a rotation portion 30b, and the rotation portion 30b is provided with a lower end side wall support portion (31, 32) and a guide wall 34. The points where the anti-slip mechanism (6c, 6d) is provided on the lower end side wall support portions (31, 32) and the points where the gap portion 33 and the guide wall 34 are provided are the same as those in the first embodiment.
Further, the connecting member 4 has the same configuration as that of the first embodiment.

15A and 15B are external views of the thoracic cavity simulator stand of Example 3, where (1) is a front view and (2) is a rear view. As shown by the arrow 7a in FIG. 15 (1), unlike the lower end support member 3 in the first embodiment, the lower end support member 30 has a structure in which the rotating portion 30b can be rotated left and right while the support portion 30a is fixed. ing. Similarly, as shown by the arrow 7b in FIG. 15 (2), unlike the upper end support member 2, the upper end support member 20 has a structure in which the rotating portion 20b can be rotated left and right while the support portion 20a is fixed. There is.
The rotating portions (20b, 30b) can be rotated with the thoracic cavity simulator 9 installed. The rotation is shifted step by step in 0.5 ° increments so that it can be fixed at any position. Therefore, further fine adjustment is possible by rotating the rotating portions (20b, 30b) after installing the thoracic cavity simulator 9 by adjusting the angle manually. Further, in order to facilitate the adjustment work, at least one of the upper end support member 20 and the lower end support member 30 may be provided with a scale indicating the degree of rotation.

FIG. 17 shows a usage flow chart of the thoracic cavity simulator stand of Example 3. As shown in FIG. 17, when using the thoracic cavity simulator stand 11, first, an organ model (not shown) is installed in the thoracic cavity simulator 9 (step S11).
Next, the folded connecting member 4 as shown in FIG. 5 (2) is extended as shown in FIG. 5 (1) (step S12). The upper end support member 20 and the lower end support member 30 are attached to the extended connecting member 4 (step S13).
The thoracic cavity simulator 9 is installed on the assembled thoracic cavity simulator stand 11 (step S14). Here, first, the installation angle is adjusted manually.
FIG. 16 is a perspective view showing a usage state of the thoracic cavity simulator stand of Example 3. Here, as in the first embodiment, the thoracic cavity simulator 9 is installed on the thoracic cavity simulator stand 11 so that the right side portion 9a of the thoracic cavity simulator 9 is on the upper side and the left side portion 9b is on the lower side. FIG. 16 shows a state in which the installation angle is adjusted by human hands and the installation is performed.
In this way, after the adjustment is manually performed and installed, the angle is further adjusted by the rotating portions (20b, 30b) (step S15). Since the adjustment by the rotating portions (20b, 30b) can be finely adjusted in 0.5 ° increments, it is possible to adjust the angle appropriately according to the purpose of training. It is also possible to change the angle during the procedure training.

The present invention is useful as a stand for a thoracic cavity simulator.

1,10,11 Stand for thoracic cavity simulator 2,20 Upper end support member 3,30 Lower end support member 4 Connecting member 4a, 4b Connecting parts 5 Hinge 6a-6d Anti-slip mechanism 7a, 7b Arrow 8a, 8b Guide marker 9 Chest cavity simulator 9a Right part 9b Left side part 20a, 30a Support part 20b, 30b Rotating part 21,22 Upper end side wall support part 23,33 Void part 24,34 Guide wall 25,35 Convex part 31,32 Lower end side wall support part 41,96 Penetration Holes 42a, 42b Recessed 91 Upper end 91a, 92a Right side wall 91b, 92b Left side wall 91c Back side wall 92 Lower end 93 Sternum 94 Spine 95 Rib R angle

Claims (10)

A stand that supports the thoracic cavity simulator in the lateral decubitus position.
An upper end support member that supports the upper end side wall of the thoracic cavity simulator,
A lower end support member that supports the lower end side wall of the thoracic cavity simulator,
It is composed of a connecting member that connects the upper end support member and the lower end support member.
The upper end support member is provided with an upper end concave gap portion between the first and second upper end side wall support portions and the two upper end side wall support portions.
The lower end support member is provided with a lower end concave gap between the first and second lower end side wall support portions and the two lower end side wall support portions.
Each of the first and second upper end side wall supports abuts on the upper end side wall of the thoracic cavity simulator.
A stand for a thoracic cavity simulator, characterized in that each of the first and second lower end side wall support portions can come into contact with the lower end side wall of the thoracic cavity simulator. The thoracic cavity simulator according to claim 1, wherein the thoracic cavity simulator can be rotated in a range of -20 to 20 ° with the vertical direction of the thoracic cavity simulator as the rotation axis direction to adjust the lateral decubitus position. Stand for. The contact of the first and second upper end side wall support portions with the upper end side wall of the thoracic cavity simulator and the lower end side wall of the first and second lower end side wall support portions of the thoracic cavity simulator. The stand for a thoracic cavity simulator according to claim 1 or 2, wherein at least one of the abutments abuts by point contact. At least one of the upper end support member and the lower end support member
The stand for a thoracic cavity simulator according to any one of claims 1 to 3, wherein a guide wall for positioning the installation position of the upper end or the lower end of the thoracic cavity simulator is provided. The stand for a thoracic cavity simulator according to any one of claims 1 to 4, wherein a non-slip mechanism is provided on at least one of the upper end side wall support portion and the lower end side wall support portion. Claims 1 to 5 are characterized in that the connecting member is detachable from at least one of the upper end support member and the lower end support member, and can be folded by a hinge mechanism provided in an intermediate portion in the longitudinal direction. The stand for the thoracic cavity simulator described in any of. The stand for a thoracic cavity simulator according to any one of claims 1 to 5, wherein the upper end support member, the lower end support member, and the connecting member are integrated. The invention according to any one of claims 1 to 7, wherein at least one of the upper end support member and the lower end support member is provided with a marker for guiding the angle adjustment of the lateral decubitus position of the thoracic cavity simulator. Stand for thoracic simulator. A rotation mechanism capable of rotating the upper end support member, the lower end support member, and the connecting member without changing the support position of the thoracic cavity simulator is further provided with the vertical direction of the thoracic cavity simulator as the rotation axis direction. The stand for a thoracic cavity simulator according to any one of claims 1 to 8. The upper end support member and the lower end support member are further provided with a rotation mechanism capable of rotating the thoracic cavity simulator itself without changing the support position of the thoracic cavity simulator with the vertical direction of the thoracic cavity simulator as the rotation axis direction. The thoracic cavity simulator stand according to any one of claims 1 to 8.