RU98114969A

RU98114969A - SIMULATOR FOR TRAINING HOW TO HELP HUMAN IN EMERGENCY CONDITIONS

Info

Publication number: RU98114969A
Application number: RU98114969/14A
Authority: RU
Inventors: В.Ф. Лутаенко; Ю.Б. Казимиров; С.О. Перфильев
Original assignee: В.Ф. Лутаенко
Filing date: 1998-07-27
Publication date: 2000-05-20

Claims

1. A simulator for teaching methods of helping a person in emergency conditions, comprising a man’s dummy, a learning process control system and a control system for this process connecting the said control device with a dummy, which includes movably interconnected: a head unit, a neck unit with a pulse simulator, a body block with an elastically deformed chest and abdomen, with a simulator of forced inflation and a heart massage sensor, upper limbs with pulse simulators and lower limbs, characterized in that the learning process control device is made in the form of an anatomical display equipped with video simulators of vital internal organs and the human skeleton frame connected to the learning process control system, and the dummy contains a set of life simulators of these internal human organs with external impact sensors also connected to the control system learning process.

2. The simulator according to claim 1, characterized in that the head unit has a detachable front and frontal-neck parts containing a frontal panel with a cavity under it, and is equipped with a device for protecting students from cross infection, which is made in the form of a removable interchangeable unit, including the specified the front part, which is a rigid mask that simulates the nasal region of a person’s face and the nasal cavity located under it and communicating with the atmosphere through a tube consisting of two detachable parts, The first part is fixedly mounted on the back wall of the nasal cavity, and the second, transparent, is freely placed in the support tube, rigidly installed in the cavity of the occipital region of the head block, opposite the hole made in the front panel, and this rigid mask contains two parts: fixed and movable, moreover, the fixed part simulates the nose and upper lip, under which a panel is installed in the form of a hemisphere with a hole simulating an open mouth, under which another, rectangular hole is made and along the edges of the specified not solid, grooves are made in the walls of the fixed part of the mask, and the movable part of the mask models the lower lip and chin and its inner side is a hemisphere, in the center of which a U-shaped bracket is rigidly fixed, and pins are installed at the edges, the diameter of which corresponds to the width of these grooves, moreover, when pairing these parts of the mask, the pins are placed with the possibility of movement in the grooves, and the U-shaped bracket enters the specified rectangular hole, and a metal plate is freely placed inside the bracket, rigidly for replennaya on the fixed part of the mask panels, retaining thereby the movable part of the mask in conjunction with the fixed part.

3. The simulator on PP. 1 and 2, characterized in that it is equipped with an artificial respiration sensor combined with a simulator of obstruction of the respiratory tract of a person, which contains a spring-loaded metal cup placed in the transparent part of the tube with the ability to move along it and a meter with a receiver mounted against each other in the supporting wall tubes and connected to the learning process control system, and the airway obstruction simulator contains said metal cup, an electric coil mounted motionless and covering guide support tube in the zone of the metal cup that is connected to a control system and a sleeve with a calibrated orifice installed in a transparent portion of the tube immediately below the bottom of the metal cup.

4. The simulator according to claim 2, characterized in that the head unit is equipped with a mechanism for extending the lower jaw containing an electronic magnet fixedly mounted in the cavity of the head unit on the front panel, opposite the rectangular hole in the panel of the fixed part of the mask, connected to the learning process control system and a permanent magnet rigidly fixed to the end of the U-shaped bracket and operatively interacting with the specified electromagnet.

5. The simulator on PP. 2, 5, 4, characterized in that the mechanism for extending the lower jaw is equipped with a sensor for extending the lower jaw, which has two optoelectronic pairs installed under through holes made in the wall of the head block on the ascending branches of the lower jaw and connected to the learning process control system and the sensor opening the mouth, containing a magnetically controlled contact, fixedly mounted on the front panel of the head unit and connected to the learning process control system.

6. The simulator according to claim 1, characterized in that imitators of the eyes are installed in the head block, each of which contains a body made of a translucent material, in which at least three different-contrast filters simulating an eyeball, an iris are placed, one after the other , a wide pupil of the human eye and one opaque filter that imitates a narrow pupil, behind which there is a highlighting element connected to the learning process control system.

7. The simulator according to claim 2, characterized in that the head unit is equipped with an simulator of external temporal hemorrhage, comprising a body, one part of which is adjacent to the wall of the temporal region and is a red filter in the form of a blood spot, and underneath there is an illuminating element and an optoelectronic a pair, which is a bandage application sensor, connected to a learning management system.

8. The simulator on PP. 2 and 7, characterized in that the temporal artery pressure sensor is installed in the head block, which is an optoelectronic pair installed under the hole made in the wall of the head block in the region of the ear tragus and connected to the learning process control system.

9. The simulator according to claim 1, characterized in that the neck block is made in the form of a cylinder of rigid material, the front wall of which simulates the outer surface of the human neck, in which through holes are made in the region of the carotid arteries, and the cylinder base is made in the form of a concave hemisphere with a central hole, while the upper edge of the rear wall of the cylinder is movably connected to the lower edge of the nape of the head block, forming a hinge that allows the front surface of the neck block cylinder to slide along the edge of the head block wall in the lower chin area. :
10. The simulator according to PP.2 and 9, characterized in that the dummy is equipped with a head tilt sensor containing a permanent magnet fixedly mounted on the upper edge of the front wall of the neck block cylinder and a magnetically controlled contact mounted on the front panel of the head block in the lower part of the chin and connected to the learning process management system, operatively interacting with the specified permanent magnet.

11. The simulator according to claim 9, characterized in that the neck block is equipped with carotid artery pulse simulators fixed inside the neck block cylinder with an electromagnet installed in it, connected to the learning process control system and a permanent magnet separated by a damping pad, the permanent magnet rigidly connected to the rod, freely installed in the through hole made in the wall of the cylinder, at the location of the carotid artery.

12. The simulator according to claim 1, characterized in that the torso unit has a rigid shell with a common plate installed inside it, on which an internal panel is placed, one end of which is pivotally connected to the common plate, and the other end with a bracket rigidly mounted on it is interfaced with it with the possibility of movement, moreover, on the inner panel one external panel imitating the surface of the chest is articulated, and the other external panel is mounted on the common panel and imitates the surface of the abdomen, while the upper part hibernation body has a spherical surface whose curvature corresponds to the curvature of the base of the cylinder block and the neck there is a hole whose diameter is equal to the width of the groove made in the base of the cylinder, in which a spring-loaded bolt.

13. The simulator according to PP.2 and 9, characterized in that the dummy is equipped with a head rotation sensor, which includes a permanent magnet, rigidly mounted on the panel on the bottom side of the neck block cylinder and a magnetically controlled contact fixed to the upper part of the body block shell, opposite permanent magnet and connected to the learning process management system.

14. The simulator according to item 12, wherein the body block is equipped with a simulator of movements of the chest, containing a permanent magnet, fixedly mounted on the inner side of the panel simulating the surface of the chest, and an electromagnet connected to the control system is rigidly mounted under it on a common plate the learning process and quickly interacting with the specified permanent magnet.

15. The simulator according to item 12, wherein the torso unit is equipped with a simulator of abdominal movements, containing a permanent magnet, fixedly mounted on the inner side of the panel simulating the surface of the abdomen, under which a solenoid is rigidly mounted on a common plate connected to the learning process control system and operatively interacting with the specified permanent magnet.

16. The simulator according to claim 12, characterized in that the dummy is equipped with: an external cardiac massage sensor, an excessive force sensor during massage and a precardial shock sensor, each of which is an optoelectronic pair mounted on a common plate, respectively, next to the bracket, under it and above it, connected to the learning process management system and operatively interacting with this bracket.

17. The simulator according to claim 12, characterized in that the torso unit is equipped with position sensors of the resuscitator's hands during heart massage, each of which has an optoelectronic pair installed under a corresponding hole made in a panel simulating the surface of the chest in the region of the lateral ends of the ribs connected to the learning management system.

18. The simulator according to claim 12, characterized in that the body block is equipped with defibrillation sensors, each of which is made in the form of an optoelectronic pair installed under the through hole in the panel simulating the surface of the chest in the region of the periphery of the heart and connected to the learning process control system.

19. The simulator according to item 12, wherein the torso unit is equipped with a simulator of heart sounds, which is an electrodynamic head mounted on the inside of the panel simulating the surface of the chest and connected to the learning process control system.

20. The simulator according to claim 12, characterized in that the torso unit is equipped with a back impact sensor, which is an optoelectronic pair mounted on a common plate directly under an incision made in a shell simulating an interscapular region and connected to a learning process control system.

21. The simulator according to claim 12, characterized in that the body unit is equipped with a stomach decompression sensor made in the form of an optoelectronic pair mounted on a common plate under the free end of the panel simulating the abdomen surface, connected to the learning process control system and operatively interacting with the inner surface this panel.

22. The simulator according to item 12, wherein the torso unit is equipped with a dummy position sensor on its side, containing a plate, one end of which is movably fixed to the side wall of the common plate and an optoelectronic pair mounted on a common plate under the movable end of the plate, connected to learning process management system and operatively interacting with this end.

23. The simulator according to claim 1, characterized in that the dummy is equipped with a belt buckle model comprising a body mounted on the shell of the torso unit, in the waist region, in which a liner with a permanent magnet is mounted to move, while in the walls of the specified body , limiting the movement of the liner, permanent magnets are placed, operatively interacting with the permanent magnet of the liner and a light indicator, and holes are made in the bottom of the case, in the zone of movement of the liner, under which optoelectronic ares that are operatively interacting with the indicated insert, while the indicated indicator and optoelectronic pairs are connected to the learning process control system.

24. The simulator according to claim 1, characterized in that pulse simulators are installed in the upper and lower extremities of the dummy, combined with an arterial pressure sensor, each of which contains a body fixed under a through hole made in the limb shell in the area of the radial and femoral arteries , a through hole is made at the base of the housing and an optoelectronic pair is fixed under it, and inside the housing, with the possibility of movement, a spring-loaded pulse simulator housing is installed, comprising a rod, a permanent magnet, rigidly connected to Considerations rod and an electromagnet between which is a damping pad, wherein said optoelectronic couple and an electromagnet connected to a control system of the learning process.

25. The simulator according to claim 1, characterized in that the upper and lower extremities of the dummy have simulators of external bleeding combined with a bandage sensor, each of which contains a body, one part of which is adjacent to the wall of the limb shell in the forearm and lower leg, It is a red filter in the form of a blood spot, under which a highlighting element and an optoelectronic pair are placed, which is a bandage application sensor connected to the learning process control system.

26. The simulator according to p. 1, characterized in that in the upper and lower extremities of the man’s dummy are installed sensors for applying a hemostatic tourniquet, each of which contains an optoelectronic pair installed under a through hole made in the limb shell, in the shoulder and hip region, connected to learning management system and operatively interacting with a hemostatic tourniquet.

27. The simulator according to claim 1, characterized in that the upper and lower extremities are equipped with sensors for applying immobilization tires, each of which contains at least two optoelectronic pairs installed under a through hole made in the dummy shell in the forearm and hip connected to the learning process control system and operatively interacting with immobilization tires.

28. The simulator according to claim 1, characterized in that it is equipped with a simulator of electric defibrillation, which includes: a defibrillation circuitry located in the anatomical display housing and defibrillation sensors installed in the model and connected to the learning process control system, as well as two remote electrodes connected to a defibrillation circuit and operatively interacting with defibrillation sensors.