WO2019206705A1 - Simulation manikin having an adjustable compression depth - Google Patents

Abstract

The present invention relates to a simulation manikin (10) for simulating and/or practicing a chest compression of a human body, comprising an artificial rib cage (12), wherein: the artificial rib cage (12) has an artificial sternum (14); the artificial rib cage (12) can be periodically pressed to at least one first adjustable compression depth or to at least one second adjustable compression depth by means of the sternum (14) and/or by means of at least one surrounding region (16) of the sternum using a simulated chest compression and a corresponding pressing movement; the pressing movement to the first compression depth can be limited by at least one first stop (18) and the pressing movement to the second compression depth can be limited by at least one second stop (20); and the second stop (20) can be displaced relative to the first stop (18), in particular by means of a translational movement, so that the first and second compression depths can be adjusted, in particular independently of one another.

Description

 Simulation doll with adjustable pressure depth

The present invention relates to a simulation dummy for simulation and / or exercise of a cardiac massage of a human body, comprising an artificial thorax, wherein the artificial thorax comprises an artificial sternum, wherein the artificial thorax by means of the sternum and / or by means of at least one surrounding region of the sternum by a simulated cardiac massage and a corresponding indenting movement in at least a first adjustable pressure depth or at least a second adjustable pressure depth is periodically pressed.

The most realistic simulation of a cardiac massage can be carried out and trained on simulation dolls, regardless of emergencies. In order to be able to represent the cardiac massage even more realistically, training devices or simulation dolls for simulating and / or practicing a cardiac massage of a human body are already known from the prior art, in which the pressure depth can be adjusted.

Thus, EP 2 437 236 A1 discloses an apparatus for simulating cardiopulmonary resuscitation techniques, the apparatus comprising a pressure adjustment piece disposed in a central region of a base and intended to assume a first position in which an upper height stop the deformation of a chestpiece, when subjected to pressure, limits a second position in which a lower height limit limits the deformation of the chestpiece.

Further, US 6,736,643 82 discloses an adult Z baby and infant doll for cardiopulmonary resuscitation comprising a body simulation with a curved mounting surface, a head simulation with an associated neck attachment. For attachment of the head simulation to the hull simulation with the arcuate connection in contact with the arcuate mounting surface fastening elements are also provided. The fasteners are movable in an arc over an arcuate mounting surface. In addition, EP 2 871 631 A1 discloses a portable medical training manikin having a hollow trunk body and a chest plate with slotted apertures which allow for realistic flexing of the chest plate along hinges which engage a breast compression piston. A chest compression piston supports and resists chest compressions performed by a user. The chest compression piston is engaged with the central chest plate of the trunk body by a quick release mechanism with snap locks to secure the piston connected to the chest plate.

Incidentally, US 2007/054254 A1 discloses a medical training device with an improved mussel shell torso arrangement. In addition, an electro-mechanical indicator is provided which displays in real time feedback about the rate of compression of the cardiac massage impressed by a practitioner on the exercise doll of the present application. The feedback by the device may preferably be by visual indicators, but may also include or alternatively have audio indicators or signals, such as words or sounds, to indicate whether or not the exerciser is compressing within the preferred guessing range and / or degree the variance in the student's compression sequences.

Due to the structurally complex boundary devices for the compression depth of a simulation doll such simulation dolls are complex and accordingly more error-prone and expensive.

It is the object of the present invention to further develop a simulatory dome of the type mentioned in an advantageous manner, in particular to the effect that the simulation doll is constructed mechanically simpler and more reliable.

This object is achieved by a simulation doll with the features of claim 1. Thereafter, it is provided that a simulation doll for simulating and / or exercise of a cardiac massage of a human body is provided with an artificial rib cage, wherein the artificial rib cage has an artificial sternum, wherein the artificial rib cage by means of the breastbone and / or by means of at least one surrounding region of the Breastbone by a simulated cardiac massage and a corresponding indentation in at least a first adjustable pressure depth or at least a second adjustable pressure is periodically pressed, wherein the indenting movement in the first pressure depth can be limited by at least one first stop and in the second pressure depth by at least one second stop can be limited, wherein the second stop relative to the first stop, in particular by a translational movement, is displaceable, so that the first and the second pressure depth, in particular independently, are adjustable.

The invention is based on the basic idea that by setting a first and second pressure depth, the exercise of a cardiac massage on the artificial rib cage can be performed even more realistic. In particular, for example, a thorax of an adult can be simulated by the first pressure depth, whereas the second, smaller, pressure depth of the chest of a child or adolescent can be simulated. In order to provide the most reliable possible adjustment of the first and second stop, a structurally as simple as possible constructed adjusting mechanism is provided, which is integrated into the simulation doll. This simple adjustment can be ensured in particular by a mechanically and structurally particularly easily implementable displacement of the second stop relative to the first stop. This displacement movement is formed by a translational movement. Such translational movement requires a minimum of guide components (such as rails, grooves, bearings, etc.) and guided components such as (carriages, extensions, dogs, etc.), whereby the first and second pressure depths are independently and safely trained by a trainee Person are adjustable.

Incidentally, it may be provided that the first stop is designed in the form of at least one projection and rises in an opposite region of the artificial sternum from the artificial thorax, wherein in particular the first stop rises in the direction of the artificial sternum. The embodiment as a projection or extension or elevation offers a structurally very simple possibility, the first stop of the artificial rib cage train. The location in the opposite region of the artificial breastbone is therefore particularly important in order to define a most accurately arranged counterpart to the artificial sternum, so that it can be ensured at each indentation that the sternum is limited in the set pressure. The first stop is designed as a substantially U-shaped or partially annular stop.

It is also conceivable that the first stop is integrally and immovably connected to the artificial rib cage. The one-piece connection with the artificial rib cage provides above all for the stable, immovable or an immovable and static position of the first stop. As a result, the positional accuracy of the first stop can be further improved, from which a very precisely arranged counterpart to the sternum is defined and the handling properties of the simulation doll can be further improved.

In addition, it is conceivable that the second stop is coupled to at least one guide mechanism and by means of the guide mechanism relative to the first stop by a Translatidnsbewegung is displaced. The guide mechanism is therefore particularly important and advantageous for the use of the second stop, because by means of the guide mechanism, the translational movement of the second stop with respect to the first is made possible in the first place. Due to the translational movement of the second stop, the guide mechanism can be constructed structurally particularly simple and with few required components. Incidentally, this simplification ensures a particularly space-saving second stop or guide mechanism that is inexpensive to produce.

It is also possible that the second stop by means of the guide mechanism between at least one non-stop position and at least one stop position is displaced back and forth. The change between a stop position and a non-stop position allows only the change of the pressure depth of the artificial rib cage, because the second stop has a greater height than the first stop and thus reduces the pressure depth. Thus, the second stop for the artificial sternum forms the second pressure depth only in the case of a stop position, which simulates the Heart pressure massage can be made more realistic by the simulation doll and thus improved.

Furthermore, it can be provided that the second stop can be latched by means of the guide mechanism in the non-stop position and in the stop position. The locking improves especially the positional fidelity of the second stop in the stop position and in the non-stop position. The positional fidelity is particularly important for safe handling of the simulation doll, as an accidental change of the stop positions should be avoided in any case. Thus, the locking further improves the reliability of the simulation doll, which also results in an improved training of the person to be trained or practicing. Furthermore, it can be provided in this context that the second stop in the stop position and in the non-stop position is clamped, clamped, clipped or otherwise releasably fastened positioned. In this case, the attachment can be made in particular positive or non-positive.

It is also conceivable that the first stop has at least one planar stop surface, on which the second stop rests and between the non-stop position and the stop position is displaceable. This type of support improves in particular the support properties of the second stop and its guiding kinematics with respect to its guide mechanism. The planar stop surface also ensures the simplest possible Abstützgeometrie the second stop. Overall, therefore, the mechanical structure of the second stop is simplified because it no longer has to be supported separately. In addition, the stability of the second stop can be improved by such interaction of the first and second stop. Furthermore, it can be provided that the translational movement of the second stop is limited by a translation stop of the first stop. In addition, the planar design of the stop surface ensures a defined stop surface for the artificial sternum.

In addition, it is conceivable that the second stop is supported on the guide mechanism by means of at least one first support and by means of at least one second support. The first and second supports transmit the Displacement movement of the guide mechanism on the second stop, so that it is only displaceable between a stop position and a non-stop position. The first and second support further allow a very space-saving connection between the second stop and guide mechanism, because they form in the mounted state of the first and second stop substantially two vertically arranged support elements. In addition, the posts further improve the stability and positional stability of the second stop in the stop position. The first and the second support are otherwise integrally connected to the second stop. As a result, in particular the rigidity of the second stop and also of the guide mechanism can be improved.

Furthermore, it is possible that the guide mechanism has at least one actuating element, by means of which the second stop between the non-stop position and the stop position is displaceable. The actuating element allows a person to be trained or a practicing person to change the first and second stop within a short time. In this case, the actuating element is arranged as a driver on a relative to the artificial thorax movable component on the guide mechanism, so that the displacement movement, starting from the actuating element particularly simple directly to the guide mechanism and thus directly to the second stop is transferable.

In addition, it can be provided that the actuating element is passed through at least one opening of the artificial rib cage in an opposite region of the artificial sternum, so that the actuating element can be actuated from outside the artificial rib cage. The actuation of the actuating element from outside the artificial thorax presents a particularly simple and comfortable way for the person to be trained to make the change in pressure by a simple displacement movement of the actuator. Particularly with frequently changing pressure depths, the simplest possible adjustment option represents a decisive improvement in the manageability of the simulation doll. The arrangement on the opposite region of the thorax ensures, in particular, that there is a Improvement of the safety of the simulation doll, because the actuating element is concealed during the heart pressure massage due to the bottom-side arrangement of the simulation doll. Thus, the actuator can not be adjusted without authorization during training on the simulation doll.

Furthermore, it is conceivable that the guide mechanism is designed as a linear guide. A linear guide as in the present case offers in particular the possibility or the advantage that the displacement of the second stop from the stop position to a non-stop position is particularly simple, short and therefore inexpensive ausgestaltetbar, since the complex storage of rotating components are dispensed with can. Furthermore, it can be provided that the inertial diet is designed as a slide bearing linear feed. This embodiment additionally reduces the number of parts, complexity and susceptibility to error of such a guide and thus ensures a further improvement of the reliability and life of the simulation doll.

It is also conceivable that the linear guide has a linearly displaceable guide carriage, which comprises the actuating element and which is coupled via the first and the second support with the second stop, so that the second stop by means of the guide carriage between the non-stop position and the stop position linearly displaceable is. A linear guide offers in the present case the advantage that the components necessary for the design of the linear guide, such as the guide rails and the guide slide, can be constructed as simply as possible, since no mechanically highly complex and highly accurate guiding tasks have to be assumed. In this respect, in particular the distribution and the use of materials can be optimized, which leads to a more cost-effective simulation doll.

It can further be provided that the linear guide has two rails, between which the guide carriage is guided linearly displaceable. Rails are mechanically very flat on the one hand and still offer on the other hand, due to their straight shape, a very good leadership quality or leadership quality of guided by them guide carriage. Incidentally, the rails can also be connected in one piece to the artificial thorax on the opposite side of the artificial sternum. This kind of Connection increases the stability and rigidity of the rails on the one hand and the entire guide mechanism on the other side. Furthermore, it can be provided that the linear guide also has more than two rails or a rail.

Further details and advantages of the invention will now be explained in more detail with reference to an embodiment shown in the drawings.

Show it:

Fig. 1 is a plan view of an embodiment of an inventive

 Simulation doll in open condition;

FIG. 2a shows a perspective detailed view of the first and second stop of the simulation doll according to the invention according to FIG. 1; FIG.

2b shows another perspective detail view of the first and second

 Attack of the simulation doll according to the invention shown in FIG. 1; and

Fig. 3 is a rear view of the embodiment of the invention

 Simulation doll according to FIG. 1 in the closed state.

1 shows a plan view of an embodiment of a simulation doll 10 according to the invention in the opened state.

The simulation doll 10 for simulating and practicing a cardiac massage of a human body is constructed according to FIG. 1 from a first and from a second shell-shaped housing part 10a, 10b.

The two shell-shaped housing parts 10a, 10b are by means of a circumferential connecting groove of a shell-shaped housing part 10a, 10b and a corresponding shape of their corresponding circumferential connecting projection of the other shell-shaped housing part 10a, 10b plugged into each other.

The first cup-shaped housing part 10a is arranged on the bottom side in the mounted or nested state.

Thus, the second shell-shaped housing part 10b is arranged in the nested state on the first, bottom-side, shell-shaped housing part 10a and fastened. Furthermore, the two shell-shaped housing parts 10a, 10b can be fastened to one another in the inserted state by means of a plurality of screw connections.

The simulation dummy 10 further has an artificial thorax 12, wherein the artificial thorax 12 in turn has an artificial sternum 14.

In the region of the artificial sternum 14, the simulation doll has a sternum extension 14a positioned within the artificial thorax 14.

The sternum extension 14a rises from an inner surface of the thorax 12, starting from the sternum 14, in the direction of the first and second stops 18, 20.

Furthermore, the sternum extension 14a forms on a first and second stop 18, 20 end facing a planar stop surface 14b, by means of which the sternum extension 14a on the first and second stops 18, 20 can be stopped

The sternum extension 14a is formed as a U-shaped support structure and integrally formed on the simulation doll.

The artificial thorax 12 is periodically depressible by means of the breastbone 14 and by means of a surrounding region 16 of the sternum 14 by a simulated cardiac massage and a corresponding indentation movement into a first adjustable pressure depth or at least one second adjustable pressure depth.

The Eindrückbewegung in the first pressure depth can be limited by a first stop 18.

The Eindrückbewegung in the second pressure depth can be limited by a second stop 20.

The first pressure depth is greater than the second pressure depth.

The second stop 20 is further displaceable relative to the first stop 18 by a translational movement.

Furthermore, in the assembled state, a spring element extends between the artificial sternum 14 and the first stop 18. The spring element is designed as a mechanical spring element for guiding the sternum extension 14a and the artificial sternum 14 relative to the first and second stop 18, 20.

The mechanical spring element is designed in the form of a helical compression spring.

The spring element is guided at its two ends in each case by means of a first guide sleeve 14c and by means of a second guide sleeve 18a radially and axially relative to its longitudinal axis.

The first guide sleeve 14c is disposed within the sternum extension 14a.

The first guide sleeve 14c is integrally connected to a plurality of (according to FIG. 1 three) support struts with the sternum extension 14a.

Further, the second guide sleeve 18 a is disposed within the first stopper 18.

The second guide sleeve 18a is further integrally connected to a plurality of (as shown in FIG. 1 three) support struts with the first stop 18.

Furthermore, the first stop 18 rises from the artificial thorax 12 in an opposite region 24 of the artificial sternum 14.

The first stop 18 is thus formed in the form of a projection 22.

The first stop 18 is designed as a stop 18 with a U-shaped or semi-annular support structure.

The first stop 18 is integrally and immovably connected to the artificial chest 12.

The first stop 18 is in particular integrally formed on the simulation doll 10.

The first stop 18 is integrally formed in particular on the opposite region of the sternum 14 on the first shell-shaped housing part 10a.

In this case, the projection 22 of the first stop 18 rises in the direction of the artificial sternum fourteenth 1, the simulation doll 10 further comprises an electronic control and regulation device SR and two output devices AI, A2.

FIG. 2 a shows a detailed perspective view of the first and second stops 18, 20 of the simulation doll 10 according to the invention, according to FIG. 1.

The first stop 18 further has a planar stop surface 28 for the stop surface 14b of the artificial sternum 14, on which also the second stop 20 partially rests in the mounted state.

The second stop 20 also has a planar stop surface 20a for the stop surface 14b of the sternum extension 14a.

The sternum extension 14b can be abutted against the abutment surface 28 of the first stop 18 in a non-stop position of the second stop 20.

Consequently, the sternum extension 14a can be abutted against the abutment surface 20a of the second stop 20 in a stop position of the second stop 20.

The respective abutment surfaces 14b, 20a, 28 of the sternum extension, the first stop 18 and the second stop 20 are arranged substantially horizontally in the assembled and ready-to-use state of the simulation doll 10 and are aligned with one another.

Furthermore, the second stop 20 is partially supported in the assembled state by means of the planar stop surface 28 of the first stop 18 in the non-stop position.

The second stopper 20 is further coupled to a guide mechanism 26.

The second stop 20 is positioned according to FIG. 2 a in a non-stop position relative to the artificial sternum 14.

The second stop 20 is further supported by means of a first support 30 and by means of a second support 32 on the guide mechanism 26.

In addition, the second stop 20 together with the first and second supports 30, 32 partially surrounds the first stop 18 in the mounted state. The second stopper 20 is integrally coupled or connected to the first support 30 and the second support 32.

The non-stop position is shown in FIG. 2a incidentally recognizable that between the first and the second support 30, 32 of the second stopper 20 and the first stop 18, a gap is formed.

The guide mechanism 26 further includes an actuator 34.

The guide mechanism 26 is also designed as a linear guide 38.

The guide mechanism or the linear guide 38 further has a linearly or linearly displaceable guide carriage 40.

The guide carriage 40 is also coupled to the second stop 20 via first and second supports 30, 32.

The guide carriage 40 is formed as a plate, at whose end facing the first stop 18, the first and two supports 30, 32 rise and the guide carriage 40 so connect to the second stop 20.

The guide carriage 40 is in this connection with the first and the second support 30, 32 integrally coupled or connected.

Furthermore, the guide carriage 40 comprises the actuating element 34.

Incidentally, the linear guide 38 has two rails 42, 44 arranged in parallel.

Between the rails 42, 44 of the guide carriage 40 is guided linearly displaceable.

Incidentally, in each case two plate-shaped securing elements 42a, 44a are releasably attached to the two rails 42, 44.

The two limiting elements 42a, 44a protrude in the assembled state into an intermediate region of the two rails 42, 44.

The limiting elements 42a, 44a form, with the guide carriage 40, a boundary for avoiding unwanted leaving of the intermediate area by the guide carriage 40 in the direction of the artificial sternum 14. FIG. 2b shows a further perspective detailed view of the first and second stops 18, 20 of the simulation doll 10 according to the invention as shown in FIG. 1.

The second stop 20 is positioned according to FIG. 2 b in a stop position relative to the artificial sternum 14.

The stop position can be recognized by the fact that substantially no gap is formed between the first and second supports 30, 32 of the second stop 20 and the first stop 18.

The second stop 20 has, moreover, a recess 20b for the spring element.

Thus, the second stop 20 at least partially surrounds the spring element in its stop position.

As a result, the spring element extends at least partially into the recess of the second stop 20 in the stop position 20b.

According to FIG. 2 b, a linear stop 46 is integrally formed on the simulation doll 10 for limiting the linear movement of the guide carriage 40.

The linear stop 46 is correspondingly formed in the region of the respective ends of the first and second rails 42, 44, which are remote from the first stop 18.

According to FIGS. 1, 2a and 2b, contact sensors 48, 50 for detecting an actual heart pressure frequency of the periodically depressible artificial sternum 14 or its surrounding area 16 are arranged on the abutment surface 28 of the first stop 18 and on the abutment surface 20a of the second stop 20.

The contact sensors 48, 50 are also electrically connected via corresponding cables (not shown in FIGS. 1, 2a, 2b) to the control and regulation device SR according to FIG.

FIG. 3 further shows a rear view of the embodiment of the simulation doll 10 according to the invention according to FIG. 1 in the closed state.

Therein a rear view of an artificial breastbone 12 opposite the artificial breastbone 14 is shown. The actuator 34 is passed through an opening 36 of the artificial chest 12 in the opposite region 24 of the artificial sternum 14.

The actuating element 34 is formed as an arcuate projection and integrally formed on one of the opening 36 facing side of the guide carriage 40.

The function of the simulation dummy 10 according to FIGS. 1 to 2b can now be described as follows:

The simulation doll 10 can be found by a practicing person as a rule for exercise and simulation purposes of a cardiac massage in an assembled or closed state.

If the simulation doll 10 is in an operational state, the practicing person or person to be trained can begin the simulation of the cardiac massage.

The following statements are based on the fact that the person practicing or to be trained carries out a continuous cardiac massage.

Accordingly, the practicing person can push the artificial sternum 14 or its surrounding area 16 as evenly as possible periodically into the artificial thorax 12 until the artificial sternum 14 strikes the first or second stop 18, 20.

The provision of the artificial sternum 14 in a non-compressed initial state of the thorax 12 is effected by the mechanical spring element.

Another function of the spring element is the formation of realistic elastic compression properties of the artificial rib cage 12.

The push-in movement into the first or the second pressure depth can be limited either by the first or the second stop 18, 20.

In this case, the first stop 18 limits the first pressure depth, whereas the second stop 20 limits the second pressure depth in its stop position. Thus, a heart pressure massage of an adult human is simulated by means of the first stop 18.

Accordingly, by means of the second stop 20 in its stop position, a cardiac massage of a young person or a child is simulated.

To change the first and second pressure depth, it is sufficient if the second stop 20 is moved relative to the first stop 18 between its stop position and its non-stop position.

In the non-stop position, the first stop 18 limits the artificial sternum 14 in the first pressure depth, wherein in the stop position of the second stop 20 limits the artificial sternum 14 in the second pressure depth

For the conversion from the first to the second pressure depth, the practicing person or the person to be trained can pass by displacing the second stop 20 as follows:

Accordingly, the second stop 20 is displaceable relative to the first stop 18 by a translational movement.

The second stop 20 is displaceable relative to the first stop 18, in particular between the non-stop position and the stop position.

As a result, the first and the second pressure depth are independently adjustable.

The second stop 20 is further displaced by means of the guide mechanism 26 between the non-stop position and the stop position back and forth.

Thus, by means of the guide mechanism 26, the second stop 20 is displaceable relative to the first stop 18 by a translational movement

For this purpose, the guide mechanism 26, the actuating element 34, by means of which the second stop 20 between the non-stop position and the stop position is displaceable.

As a result, the actuating element 34 can be actuated from outside the artificial thorax 12. Further, the second stop 20 is partially on the flat support surface 28 of the first stop 18 and is there between the non-stop position and the Anschiagstetlung displaced.

The guide carriage 40 is coupled via first and the second support 30, 32 in such a way with the second stop 20, that the second stop 20 by means of the guide carriage 40 between the non-stop position and the stop position is linearly or linearly displaceable.

Furthermore, the second stop 20 can be locked by means of the guide mechanism 26 in the non-stop position and in the stop position.

For this purpose, the guide rails 42, 44 corresponding latching grooves on the stop position and on the non-stop position of the second stop 20.

Further, the guide carriage 40 corresponding to the locking grooves locking lugs, which are in the stop position and at the non-stop position of the second stop 20 with the locking grooves in a locked engagement.

Of course, the guide rails 42, 44 have the latching noses and accordingly the guide carriage, the locking grooves.

The linear movement of the guide carriage 40 is further limited in the direction of the first stop 18 by a translation stop of the first stopper 18, so that guide carriage 40 can assume its stop position.

Further, by means of the linear stop 46, the linear movement of the guide carriage 40 away from the first stop 18 can be limited, so that the guide carriage 40 can assume its non-stop position.

The control and regulation device SR according to FIG. 1 is also set up to control and regulate the simulation dummy 10 and the output devices AI, A2.

For this purpose, the respective contact sensors 48, 50 on the first and second stops 18, 20 detect a contact signal which then transmits the contact signal further to the control and regulation device SR. Based on the contact signal, the control and regulating device SR determines an actual cardiac pressure.

By means of the control and regulating device SR, a desired cardiac pressure can be further generated, which can be output by means of the first or second output device A1, A2.

The actual heart pressure frequency can then be displayed by the first or the second output device A1, A2 or by both output devices A1, A2.

By means of the control and regulating device SR, a frequency difference between the actual cardiac pressure and the desired cardiac pressure can also be determined.

Based on this frequency difference is then by means of the control and regulation device SR generated in a difference signal.

The difference signal can then be output or displayed by means of the first or second output device A1, A2 or by means of the first and second output devices A1, A2.

In this case, the first output device AI is positioned in a first surface area of the simulation doll 10, which is arranged in a field of view of the person to be trained.

Furthermore, the second output device A2 is positioned in a second surface area of the simulation doll 10, which is not in the field of vision of a person to be trained.

LIST OF REFERENCE NUMBERS

10 simulation doll

 10a first shell-shaped housing part

 10b second shell-shaped housing part

 12 artificial ribcage

 14 artificial sternum

 14a sternum extension

 14b stop surface of the sternum extension

 14c first guide sleeve

 16 surrounding area of sternum

 18 first stop

 18a second guide sleeve

 20 second stop

 20a stop surface of the second stop

 20b recess of the second stop

 22 lead

 24 opposite area of the artificial sternum

26 guide mechanism

 28 stop surface of the first stop

 30 first support

 32 second support

 34 actuator

 36 Opening of the artificial rib cage

 38 linear guide

 40 guide carriages

 42 guide rail

 42a fuse element

 44 guide rail

 44a fuse element

 46 linear stop

 48 contact sensor

50 contact sensor SR control and regulation device

A1 first output device

 A2 second output device

Claims

claims

A simulated dummy (10) for simulating and / or exercising a cardiac massage of a human body comprising an artificial thorax (12), the artificial thorax (12) comprising an artificial sternum (14), the artificial thorax (12) using the artificial thorax (12) Breastbone (14) and / or by means of at least one surrounding area (16) of the sternum by a simulated cardiac massage and a corresponding indentation in at least a first adjustable pressure depth or at least a second adjustable pressure depth is periodically eihdrückbar, wherein the indenting movement into the first pressure by at least a first stop (18) is limited and in the second pressure depth by at least one second stop (20) can be limited, wherein the second stop (20) relative to the first stop (18), in particular by a translational movement, is displaceable, so that the first and the second pressure depth, in particular independently, one are adjustable.

2. simulation doll (10) according to claim 1, characterized in that the first stop (18) in the form of at least one projection (22) is formed and in an opposite region (24) of the artificial sternum (14) from the artificial chest ( 12), wherein, in particular, the first stop (18) rises in the direction of the artificial sternum (14)

3. simulation doll (10) according to claim 1 or claim 2, characterized in that the first stop (18) is integrally and immovably connected to the artificial rib cage (12).

4. simulation doll (10) according to claim 1, characterized in that the second stop (20) is coupled to at least one guide mechanism (26) and by means of the guide mechanism (26) relative to the first stop (18) by a translational movement is displaceable.

5. simulation doll (10) according to claim 4, characterized in that the second stop (20) by means of the guide mechanism (26) between at least one non-stop position and at least one stop position is displaced back and forth.

6. simulation doll (10) according to claim 4 or claim 5, characterized in that the second stop (20) by means of the guide mechanism (26) can be latched in the non-stop position and in the stop position.

7. simulation doll (10) according to claim 5 or claim 6, characterized in that the first stop (18) aulweist at least one planar stop surface (28) on which the second stop (20) rests and between the non-stop position and the stop position is displaceable.

8. simulation doll (10) according to one of claims 4 to 7, characterized in that the second stop (20) by means of at least one first support (30) and by means of at least one second support (32) on the guide mechanism (26) is supported.

9. simulation doll (10) according to one of claims 4 to 8, characterized in that the guide mechanism (26) has at least one actuating element (34) by means of which the second stop (20) between the non-stop position and the stop position is displaceable.

10. simulation doll (10) according to claim 9, characterized in that the actuating element (34) through at least one opening (36) of the artificial rib cage (12) in an opposite region (24) of the artificial sternum (14) is passed, so that the actuating element (34) from outside the artificial rib cage (12) is actuated.

11. simulation doll (10) according to one of claims 4 to 10, characterized in that the guide mechanism (26) is designed as a linear guide (38)

12. simulation doll (10) according to claim 11, characterized in that the linear guide (38) has a linearly displaceable guide carriage (40) which comprises the actuating element (34) and the first and the second support (30, 32) with the second stop (20) is coupled, so that the second stop (20) by means of the guide carriage (40) between the non-stop position and the stop position is linearly displaceable

13. simulation doll (10) according to claim 11 or claim 12, characterized in that the linear guide (38) has two rails (42, 44), between which the Führungsschiitten (40) is guided linearly displaceable.