RU2144218C1 - Training device for acquiring first aid skills - Google Patents

Abstract

FIELD: medical devices. SUBSTANCE: device has human body plaster cast, which comprises frame, models of mouth and nose respiratory inputs, models of eye pupil reaction, model of carotid artery pulsation, inhalation valve, model of respiratory movements of chest model, and detectors of inhalation, pressure and impact. Human body plaster cast is designed as flexible jacket, which joints head, neck and body models into single housing. In addition model has anatomic patterns of human body to provide skin tuck in place, where neck model is connected to body model on back side. Jacket has two independent members, which are located in head and body models. Each member has support rests, which are located in back part of respectively head and body and are connected to lower parts of struts which are passed through simulator and which upper parts carry mounting plates. EFFECT: increased service life, increased similarity of training to real conditions. 8 cl, 5 dwg

Description

 The invention relates to medicine and can be used in practicing techniques and acquiring the necessary skills in providing first aid to victims.

 A known simulator for practicing first aid techniques for the victim, made in the form of a dummy of the human body, consisting of a block of the head and a block of the body. In the head unit, a breathing valve is installed through the mouth, connected by a nozzle to a pneumatic capacity of variable volume mounted in the body unit. The capacity elements of the variable volume are connected to the potentiometer, and when air is supplied to it through the breathing valve, the potentiometer registers the amount of air supplied (US patent 4932879 from 1990, NKI 434/262). The disadvantage of the simulator is that it is designed to train in only one first-aid treatment: inhalation through the mouth.

 Also known is a simulator of the same purpose, containing a dummy of a person without upper and lower extremities and including a head block with a nasal-oral entrance, a neck block with a pulse simulator, pivotally connected to a head block, and a body block consisting of a chest with an elastically deformable front panel under which the simulator of filling the stomach is placed. The simulator is equipped with a system of resuscitation sensors connected to the dummy and containing a system of simulators of human recovery: eye simulators, pulse on the carotid artery, respiratory movements (US patent 4850876 from 1989, NCI 434-265). The disadvantage of the simulator is the articulation of the blocks of the head, neck and torso of the dummy, which, firstly, limits the possibility of changing the position of the head relative to the neck and torso when working with the dummy and, secondly, has a negative psychological effect on the trainee, because the fake in this case differs from the human body by external anatomical features.

 The closest analogue adopted for the prototype of the present invention is a simulator for practicing first aid, including a dummy of a person’s body with a skeleton, a head unit with imitators of the oral and nasal respiratory openings and eye pupil imitators, a neck unit with a simulator of pulsation of the carotid artery, a body block with the inspiratory valve and the simulator of the respiratory movements of the simulator of the chest, and the inspiratory, pressure and shock sensors. The neck block is pivotally connected to the head block and the torso block. The blocks of the head, neck and trunk are made as separately manufactured and then mounted together elements (RF patent 2124762 from 01/10/99, MKI G 09 B 23/28). As in the previous analogue, the drawback of the simulator is the presence of articulated joints of the blocks of the head, neck and torso of the dummy, which, firstly, limits the possibility of changing the position of the head relative to the neck and torso when working with the dummy and, secondly, it has a negative psychological impact on the trainee, as the fake in this case differs from the human body by external anatomical features. The loads that occur during training are transferred directly to the dummy material, which causes its rapid wear. In addition, the simulator does not make it possible to register erroneous actions of the rescuer.

 The technical result achieved by using the invention is to increase the service life of the simulator and to ensure an anatomical approximation of the learning process to real conditions.

 This result is achieved by the fact that the simulator for practicing first aid skills includes a dummy of a person’s body with a skeleton, a head block with simulators of the oral and nasal respiratory openings and eye pupil reaction simulators, a neck block with a simulator of pulsation of the carotid artery, a body block with an inspiration valve and a simulator respiratory movements of the chest simulator and sensors for inspiration, depression and stroke. The model of the human body is made in the form of an elastic shell simulator, combining the head block, neck block and body block into a single body and provided with anatomical landmarks of the human body with the formation of folds of skin in the area where the neck block adjoins the body block from the back of the simulator, and the frame consists of two independent from each other parts located in the head block and the body block, each of the parts of the frame is equipped with supporting bases located respectively in the occipital and dorsal zones of the human body and tightly connected with the lower ends of the racks passed through the shell-simulator of the human body, on the upper ends of which mounting plates are also rigidly fixed. On the supporting base of the torso block in the area of the skin fold simulator, a pivot arm is mounted with the possibility of interaction with the inspiratory valve and the skin fold simulator. The simulator of the clavicle and the simulator of the xiphoid process with pressure sensors are additionally installed on the chest simulator. The simulator of the pulsation of the carotid artery is mounted by means of an elastic plate on the mounting plate of the frame of the trunk unit and is in contact with the simulator shell. The carotid artery pulsation simulator is made in the form of an electromagnet equipped with a plate, the anchor of which is mounted to interact with this plate, on which an elastic gasket is fixed in the zone of interaction with the electromagnet anchor, the electromagnet hanging from the plate on a bracket fixed by means of a dielectric plate to the carotid installed in the carotid zone arteries of the sheath-simulator flat spring. The inspiration valve is made in the form of a housing with inlet and outlet openings, in the end of which from the outlet side a pressure rod is mounted, rigidly connected to a spring-loaded locking plate mounted in the valve body, which is installed to interact with an annular seat formed in the valve body, inside the case mounted check valve. The respiratory simulator is made in the form of a sealed bag mounted on a mounting plate of the frame body part, on which a movable plate is attached to the hinge at one end and connected by means of springs to the chest simulator, formed by a plate curved along the chest profile, also fixed by its own hinge to the mounting plate, and the axes of both hinges are parallel to each other, and the ends of the springs are rigidly connected to the movable plate of the sealed bag and to the plate of the chest simulator. The respiratory simulator is made in the form of a bellows mounted on a mounting plate of the body part of the frame, and the upper part of the bellows is connected to the chest simulator, formed by a plate curved along the profile of the chest mounted on a hinge on the mounting plate.

The invention is illustrated by drawings, which depict:
- in FIG. 1 - the general scheme of the simulator;
- in FIG. 2 - inspiratory valve;
- in FIG. 3 - simulator of cardiac activity of the carotid artery;
- in FIG. 4 - shock sensor;
- in FIG. 5 - embodiment of a simulator of respiratory movements.

 The simulator for practicing first aid skills is made in the form of a dummy 1 of a person’s body formed by blocks of the head 2, neck 3 and body 4, covered with an elastic sheath-simulator 5, uniting all three blocks in a single body. The shell simulator 5 is formed from an elastic material, for example plastisol, which allows, after molding, to preserve the shape of the human body with its anatomical landmarks. This ability of plastisol allows you to mold the block of the head 2, the block of the neck 3 and the block of the torso 4 of the human model as a single unit. In the zone 6 of the abutment of the neck unit 3 to the body unit 4 from the back 7, the simulator shell design provides for the formation of a skin fold simulator 8 when the head block 2 is tilted. Inside the simulator shell there are frames 9 and 10 made freely installed in the simulator shell 5 and consisting of two independent from each other parts 9 and 10, located respectively in the head unit 2 and the body unit 4. The frame is made of stainless material. Each part of the frame is equipped with support bases 11 and 12 located respectively in the occipital 13 and dorsal 7 zones of the human body and rigidly connected to the lower ends 14 of the struts 15 passed through the shell-simulator of the human body. Mounting plates 17 are also rigidly fixed to the upper ends 16 of the racks , 18. On the supporting base 12 of the trunk unit 4 in the area of the skin fold simulator 8, the pivot arm 21 is mounted with the possibility of interaction with the inspiration valve 20 and the skin fold simulator 8.

 On the mounting plate 17 of the head unit 2, simulators of the reaction of the pupils of the eyes 22, a simulator of the mouth 23 and the nose 24 of the respiratory openings are installed. A simulator of the reaction of the pupils of the eyes is used to simulate the narrowing of the pupils of the eyes during a correctly performed exercise: the simulator can be made in the form of a lens illuminated by an LED through a filter (not shown in the drawings). To provide the necessary stiffness when working with the simulator, the stops 25 are mounted on the mounting plate 17 of the head unit: the mouth breathing simulator is made in the form of a tube 27 enclosed in a clip 26, and the nose breathing simulator 24 is also made in the form of a tube 29 mounted on the holder 28. Both the tubes 27 and 29 are connected by a tee 30 and a pipe 31 with the inlet of the inspiratory valve 20.

In the body unit 4, on its mounting plate 18, a respiratory motion simulator 32, a chest simulator 33, and inspiratory sensors 34 and depressions 35 and 36 are installed. The respiratory motion simulator 32 can be implemented in different ways. Two of them are presented below:
1. The simulator is made in the form of a sealed bag 37 mounted on a mounting plate 18 of the frame of the trunk unit 4. On the same plate, a movable plate 39 is attached to the hinge 38 at one end thereof, connected by means of springs 40 to the chest simulator 33 formed by a chest profile curved cages with a plate also fixed by its own hinge 41 on the mounting plate 18, the axes of both hinges being parallel to each other, and the ends of the springs rigidly connected to the movable plate 39 of the airtight bag 37 and to the plate of the chest simulator 33.

 2. The simulator of respiratory movements is made in the form of a bellows 42 mounted on a mounting plate 18 of the frame of the body unit 4, and the upper part 43 of the bellows is connected to the simulator of the chest 33, formed by a plate curved along the profile of the chest mounted on a hinge 41 on the mounting plate 18. The bellows may be spring or may have an additional spring 44.

 In both solutions, an elastic pad 45 is glued on top of the chest simulator plate 33 between it and the sheath simulator 5. In addition, the clavicle simulator 46 with sensor 47 is attached to the chest simulator 33 plate, as well as the xiphoid process simulator 48 with its sensor 36. Sensors 47 and 36 signal the erroneous actions of the trainee, which can lead to a fracture of the clavicle or xiphoid process.

 On the mounting plate 18 of the frame of the torso block 4 in the area of the carotid artery 49 by means of a flat spring 50, a simulator of pulsation of the carotid artery 51 is installed, made in the form of an electromagnet 53 provided with a plate 52, the anchor 54 of which is mounted to interact with the plate 52. On the plate 52 is fixed in the zone interacting with the armature of the electromagnet elastic pad 55, and the electromagnet is suspended from the plate 52 on the bracket 56. The simulator of the pulsation of the carotid artery 51 is connected to a flat spring 50 using a dielectric plate 57, and the plate 52 is adjacent to the shell simulator 5.

 As sensors for inspiration 34 and depression 35 can be applied sealed magnetically controlled contacts of the type "reed contact", triggered by a change in position of the corresponding parts of the simulator. The fracture sensors of the clavicle 47 and the xiphoid process 36 are selected spring type, triggered by pressing or impact of a certain force.

 The shock sensor 58 is mounted on the support base 12 and is a contact pad 60 mounted in a sealed dielectric casing 59 and a holder 61 of a spring 62 fixed to the holder with one end thereof. The advantage of this sensor is that it only responds to a blow directed from top to bottom and practically does not perceive other directions of impact.

 The inspiratory valve 20 is made in the form of a body 63 with an inlet 64 and an outlet 65, in the end of which a pressure rod 66 is mounted on the outlet side and is rigidly connected to a spring-loaded locking plate 67 located in the valve body and configured to interact with an annular seat 68 formed in the valve body, and a check valve 69 is mounted inside the body. The sealed bag 37 or bellows 42 are connected by a pipe 70 to the inspiratory valve 20, and the pipe 70 has a branch 71 communicating with the atmosphere through final year at the opening 72. The diameter of the outlet (not shown) is selected in such a way that when the majority of the air 20 supplied from the valve enters the sealed bag 37 or bellows 42.

 For ventilation of the dummy, holes 73 are used.

 The model is equipped with hands 74, on the forearm 75 of one of which there is an indication unit 76 connected to the electronic unit 77 and the simulator sensors and equipped with a connector for connecting to a computer (not shown in the drawings). In the case of placing blocks 76 on both forearms, the blocks duplicate each other.

 Work with the simulator is as follows.

 Artificial respiration: the trainee throws the head block (head) 2 simulators back. Moreover, in the zone 6 of adjacency of the neck unit 3 to the body unit 4, a fold of the simulator shell 5 is formed, which presses on the lever 21, turning it around the hinge 19 and pressing on the pressure rod 66. The rod 66 depresses the locking plate 67 from the annular seat 68 - only in this position, with the head tilted back, air from the lifeguard will be able to enter the lung simulator — a sealed bag 37 or bellows 42. The lifeguard can pinch the hole of the nose simulator 24 with the fingers of one hand and inhale air through the mouth simulator 23 into the “victim”; if the rescuer forgets to pinch the nose simulator 24, then the air through the nose simulator 24 will go into the atmosphere and the inspiratory sensor 34 will not apply to the display unit of the corresponding signal. Inhaled air passes through the tubes 27, 29, the nozzle 30, the inspiratory valve 20, the nozzle 70 and then a smaller part is vented through the outlet 72 into the atmosphere, and the majority gets into the sealed bag 37 or the bellows 42, causing them to expand, which is detected by the sensor breath 34, responsive to increased air pressure. Increasing in size, the sealed bag 37 through the springs 40 and the plate 39 acts on the simulator of the chest 33, causing it to rise. When you "exhale" (lowering the simulator of the chest 33 down), air flows from the sealed bag 37 through the outlet 72 to the atmosphere. The bellows 42 works similarly.

 Indirect cardiac massage: the trainee presses with a certain frequency with both hands on the chest simulator 33, the pressure sensor 35 is triggered and the signal is sent to the display unit, and the pressure is transmitted through the springs 40 to the movable plate 39. In this case, the air from the airtight bag 37 is partially removed through the hole 72, and since the inspiratory valve 20 is blocked by the locking plate 67 (the head of the “injured” is in a normal, unrestrained position), a new portion of air does not enter the sealed bag 37. The movable plate 39 has a limited deflection boom. The pressure sensor 35 can be programmed so that when the massage is carried out correctly after a predetermined number of presses, the eye pupil reaction simulator 22 and the carotid artery pulsation simulator 51 are triggered. The pulsation of this simulator is felt by the fingers due to the fact that its plate is in contact with the simulator shell 5. The constructive implementation of the simulator of pulsation of the carotid artery 51 allows you to accurately simulate heart beats, reducing the sound vibrations that occur when the mobile armature 54 electromagnet 53. If the rescuer incorrectly conducts an indirect massage of the heart (the most common error is pressing in the area of the xiphoid process on the simulator of the xiphoid process 48), the sensor 36 of the erroneous effect is activated. The same thing happens with another rescuer error - when pressing on the simulator of collarbone 46, sensor 47 is triggered.

 When conducting an indirect massage of the heart, the cavity of the shell-simulator of the body is ventilated simultaneously through the holes 73.

 Precardial shock: the blow is applied by a sharp movement of the fist of the "rescuer" in the chest area. Due to the vibration of the entire design of the simulator, the shock sensor 58 is triggered.

 The presence of the frame 9, 10 with the supporting bases 11, 12 and racks 15 allows you to redistribute the load from the actions of the rescuer to the base 78, on which the simulator (ground, floor) is located, thereby significantly extending its service life.

The self-supporting shell simulator of the simulator, combining the head, neck and chest as a whole, encompasses the functions of the supporting structure and serves to shape the exterior of the simulator and fix its internal structure in the cavity of the shell. Thanks to this solution, it becomes possible to achieve the maximum degree of imitation of the skin and the shape of the human body:
- on the face - moving upper eyelids, nose wings, chin,
- on the neck - the relief of the nodules, cartilage of the larynx, supraclavicular fossa;
- on the chest - the relief of the jugular fossa, collarbone, costal arch and intercostal spaces, sternum, xiphoid process.

 If the simulator is connected to a computer in real time, all the simulator states necessary for training are displayed: sound and voice messages are displayed, visual pictures of the state of the organs of a person are displayed during first aid, including during erroneous actions of the trainee, etc. .

When monitoring the lifeguard training course, the electronic unit 77 can be programmed to record its individual actions. For example:
- during a precardial stroke of a certain force, a shock sensor is triggered and the signal from the sensor enters the electronic unit, which enables the simulation of the reaction of the pupils of the eyes (narrowing of the pupils) and the simulator of pulsation of the carotid artery for 1-2 minutes, after which the system returns to the standby state; in case of the rescuer making erroneous actions (striking the simulator of the clavicle or xiphoid process), the corresponding sensors generate a signal and the electronic unit displays information on the “fracture” of the xiphoid process or clavicle on the display unit; if the strength of the precardial shock is such that both the shock sensor and the pressure sensor are triggered, then the electronic unit does not include either a simulator of the reaction of the pupils of the eyes or a simulator of pulsation of the carotid artery and goes into standby mode; in this way the optimal force of precardial shock is worked out;
- during one resuscitation cycle, consisting of one or two breaths and from four to sixteen clicks on the chest simulator (if the corresponding sensors are triggered) with a break between presses of not more than 4 s, the electronic unit includes a pupil reaction simulator of the eyes, but does not include simulator of pulsation of the carotid artery; with the correct conduct of at least 8 resuscitation cycles, the electronic unit includes a simulator of pulsation of the carotid artery while the simulator of reactions of the pupils of the eyes is turned on during all resuscitation cycles;
- when holding three or more breaths, two or more precardial strokes in a row, a pause between keystrokes for more than 4 s, more than 16 keystrokes in a row, triggering of sensors for pressing simulators of the clavicle or xiphoid process, the electronic unit goes into standby mode (ready to work), which means that the process of developing first aid skills must be started again.

 The training progress tracking program is not limited to these examples and can be expanded depending on the training program for trained lifeguards.

 Given the features of resuscitation and the methodology of teaching her skills, it is recommended to place the unit 76 for indicating the results of the rescuers' actions on the left forearm. This arrangement is determined by the fact that all right-handed rescuers should be located to the right of the victim: two or three people work in the assistance team and the task of a few left-handed rescuers is to be able to quickly adapt to the rest.

 The display unit 76 during the training can be covered, and then the actions of the rescuers are evaluated only by the reaction of the simulator of the reaction of the pupils of the eyes 22, raising the simulator of the chest 33 and the simulator of pulsation of the carotid artery 51.

 The design features of the robot allow you to teach the collective actions of rescuers both in the classroom and at the training ground. When connected to a computer, the simulator will respond to all errors made by sound replicas and computer animation on the monitor screen.

Claims (8)

 1. A simulator for practicing first aid skills, including a dummy of a person’s body with a skeleton, a head unit with imitators of the oral and nasal respiratory openings and eye pupil reaction simulators, a neck unit with a simulator of pulsation of the carotid artery, a body block with inspiration valves and a simulator of respiratory movements of the simulator chest, and inspiration, pressure and shock sensors, characterized in that the dummy of the human body is made in the form of an elastic shell-simulator that combines the head block, neck block and trunk block into a single body and provides the anatomical landmarks of the human body with the formation in the area of abutment of the neck block to the body block from the back of the simulator of the skin folds, and the frame consists of two parts independent from each other, placed in the head block and the body block, each of the parts of the frame provided with supporting bases, located respectively in the occipital and dorsal zones of the human body and rigidly connected to the lower ends of the racks passed through the shell-simulator of the human body, the upper ends of which are also rigidly fixed s plate.  2. The simulator according to claim 1, characterized in that the clavicle simulator and the xiphoid process simulator with pressure sensors are additionally installed on the chest simulator.  3. The simulator according to claim 1, characterized in that the simulator of the pulsation of the carotid artery is mounted by means of an elastic plate on the mounting plate of the frame of the trunk unit and is in contact with the simulator shell.  4. The simulator according to any one of claims 1 or 3, characterized in that the simulator of the pulsation of the carotid artery is made in the form of an electromagnet equipped with a plate, the anchor of which is mounted to interact with this plate, on which an elastic gasket is fixed in the zone of interaction with the electromagnet anchor, the electromagnet is suspended from the plate on a bracket fixed by means of a dielectric plate to a plane spring mounted in the region of the carotid artery of the sheath-simulator.  5. The simulator according to claim 1, characterized in that the inspiration valve is made in the form of a body with inlet and outlet openings, in the end of which a push rod is mounted on the side of the outlet, rigidly connected to a spring-loaded locking plate installed with the possibility of interaction with an annular seat formed in the valve body, and a check valve is mounted inside the body.  6. The simulator according to claim 1, characterized in that the simulator of respiratory movements is made in the form of a sealed bag mounted on a mounting plate of the frame of the trunk unit, on which a movable plate connected by means of springs to the chest simulator formed by a curved one is fixed on its hinge along the chest profile with a plate, also fixed with its own hinge on the mounting plate, the axes of both hinges being parallel to each other, and the ends of the springs rigidly connected to the movable plate of the sealed bag and chest simulator plate.  7. The simulator according to claim 1, characterized in that the simulator of respiratory movements is made in the form of a bellows mounted on a mounting plate of the frame of the body block, and the upper part of the bellows is connected to the simulator of the chest, formed by a plate curved along the profile of the chest mounted on a hinge on mounting plate.  8. The simulator according to claim 1 or 5, characterized in that a pivot lever is mounted on the hinge of the skin fold simulator in the area of the skin fold simulator with a possibility of interaction with the inspiratory valve and the skin fold simulator.

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