DE20315975U1 - Breathing apparatus control device, especially for a medical emergency breathing apparatus, has an operating controller that is temporally switched between measurement and regulation phases in a real-time control cycle - Google Patents

Abstract

Control device for a breathing apparatus, has at least one sensor for measuring a breathing parameter and at least a regulator for output of an adjustment or operating value. The regulator is connected to a operating controller that is continuous temporally switched between measurement and regulation phases within a real-time control cycle.

Description

The invention relates to a device for controlling a ventilator, the at least one sensor for detecting a ventilation parameter and at least one controller for specifying a control value, which is connected to a sequence control.

Such control devices are for different ventilators used. For example, you can this equipment to carry out Be emergency respirations. The control devices can but also with other ventilators be used for Pressure Support Ventilations are used and typically during sleep of patients come into use.

The devices are in different Designs used in the medical field. Basically between applications in the mobile area as well as in the stationary area distinguished. Mobile applications can be found especially in prehospital Use in primary transports, Secondary transport as well as in intra-hospital transports. Other applications can be found in the quasi-stationary Given in the known stationary clinical devices for economic or logistical considerations not used can come.

Stationary applications are mainly in the clinical area given to a high quality patient care to ensure.

The hitherto known mobile ventilation devices, the predominantly during execution of transport breaths work essentially according to a clocked air pump, at predetermined time intervals introduces a given volume of breathing into the patient's lungs and in intermediate relaxation phases an escape of the respiratory air permits or this is actively supported. Possibly. existing residual capabilities of the patient to the independent execution the respiratory processes usually not considered here. As a consequence, that the Restatmungsfunktion the patient in carrying out the transport ventilation on can lose weight.

Generally, the problem with performing ventilator control is that that one A-daption to a respective current physiological state the patient is desired. Therefore, with high-quality controls both a metrological Detection of at least one ventilation parameter as well as an adaptation carried out by Control processes or control processes to the respective application situation.

Especially with complex forms of ventilation with different baseline pressure levels, so-called bilevel ventilations, is the effort to control the pressure in a pressure-controlled ventilation or the flow in flow-controlled or volume-controlled Ventilations very high. The control and regulation units are typically equipped with microprocessors, the corresponding Process rule algorithms. Typically, such is Processing in the area of the central computer unit of the ventilator localized. The sensor signals must are processed in real time and it is also necessary the drive signals for the associated actuators, such as valves or blowers, in real time provide. For longer Processing times are sometimes significant regulatory errors. to shortening Processing times are becoming increasingly expensive processor systems with high efficiency used.

Another problem is that at software-based Sequential control in addition For the implementation of real-time control also other functional areas of the device need to be covered the due to metrological detected triggering situations or due to manual input. Typically, next to The actual control function also functions in terms the measurement of respiratory physiological parameters, monitoring the device function, a control of a display, a query of the controls, the handling of alarm messages as well as the data storage are carried out.

Particularly problematic are the Calculation and monitoring of respiratory physiological variables, for example tidal volume and pulmonary impedance as well as detection and processing situational parameters, such as the occurrence of leaks. A high quality coping these application situations leads to high demands on both the hardware used and to the software.

Object of the present invention it is, a device of the kind mentioned in the introduction to such construct that one high quality device function at the same time high reliability and clearer System structure is provided.

This object is achieved according to the invention solved, that the Sequence control temporally alternating measuring phases and control phases specified and that the Regulator is designed as part of a real-time control.

The realization of the sequence control in such a way that alternating measuring phases and control phases are carried out makes it possible to carry out a very extensive decoupling of the respective control elements as well as of the associated software modules. This decoupling leads to a very large clarity of the system structure and facilitates commissioning and possibly required troubleshooting during system production. In particular, the realized temporal decoupling of the system functions leads to a simple processing structure which supports the execution of additional functions to be performed regularly or spontaneously.

According to an exemplary application is provided that the ventilator as an emergency ventilator is trained.

To support mobile applications it proves to be advantageous that the ventilator in the area a transport case is arranged.

A simple system structure will also supported by that the Sequence control the measuring phases in periodically recurring time intervals pretends.

To improve the adaptive system properties Is it possible, that the time interval of measuring phases dependent on of at least one metrological detected Parameter is specified.

In particular, to improve the existing processing capacity thought that during the execution a measuring phase disables a control module and activates a control module is.

To approximate the control behavior a real-time control is proposed that the controller for processing a history-based actuator control signal is formed.

A typical system design is done such that on a measuring phase a number of n control phases with n> 1 are given.

A preferred field of application is that the Regulator for support a bilevel ventilation is formed.

To support an optimal implementation of the control operations it is proposed that at least temporarily a memory for recording at least one signal is activated.

An approximation of the control behavior a regulatory behavior is made possible in particular by that one Arithmetic unit for determining at least one time-average control signal is used.

A device realization is to that the Control unit designed to control at least one valve is.

According to a further embodiment variant provided that the Control unit for controlling at least one blower formed is.

A high application flexibility at the same time compact device geometry is achieved by the Control unit realized at least partially as a software is.

In the drawing, embodiments of the Invention shown schematically. Show it:

1 a perspective view of an arranged in a suitcase emergency ventilation system,

2 a schematic block diagram illustrating the control flow as well as used system components and

3 a simplified block diagram illustrating the structure of the control unit.

1 shows a ventilator ( 1 ) designed to carry out emergency respirations and stored in a carrying case ( 2 ) is arranged. The ventilator ( 1 ) is equipped with a control unit ( 3 ), the operating elements ( 4 ) as well as ads ( 5 ) having. A supply of the respiratory gas to a patient is carried out using a breathing tube ( 6 ) as well as a breathing mask ( 7 ).

2 illustrates in principle the operation of the control unit ( 3 In carrying out a speed control for a blower for the promotion of the breathing gas. After passing through a start module in which a predefinition of control and control parameters takes place, a query is first made as to whether a predefined breath number exists. It is specified here that a cycle of altogether m breaths is passed through, of which the first m-1 breaths are pressure-controlled and the m-th breath speed-controlled.

If the evaluation shows that not yet the mth If there is a breath, activation of the module for real-time pressure regulation takes place subsequently a recording of the speed pattern n (t) of the turbine. The speed pattern corresponds to the speed function of the current breath.

After recording the speed pattern is a calculation of the average pattern over those already completed breaths carried out. For example, a number of m-1 breaths can be considered here that were last traversed. The determined average value is stored and fed to a speed control.

Subsequently, a new query, whether already the mth Breath is reached, at which no regulation but a control be performed should. If this breath is present, the speed control is activated and the speed under consideration of the last determined average speed value. At the next subsequent breath then takes place again a scheme.

3 illustrates in a block diagram representation of the basic device structure. It can be seen that the control unit ( 3 ) a controller ( 8th ), a sensor ( 9 ) for metrological monitoring of the ventilator ( 1 ) as well as a sequence control ( 10 ) having. The flow control ( 10 ) includes a clock preset ( 11 ) as well as a setpoint memory ( 12 ). Via an input ( 13 ) manual specifications can be considered.

By the in 3 illustrated structure of the control unit ( 3 ) It is possible during the breath, in which the real-time control by a historian-based actuator control signal is replaced to use the freed-up processing capacity for measuring operations and / or the performance of memory operations. As an alternative to unweighted averaging over a predetermined number of breaths, weighted averaging may also be performed in which the last breaths passed are of greater weight than the more recent breaths.

It is also conceivable to carry out a filtering when carrying out the averaging, which ignores sporadic clear deviations from a mean system behavior. The respective system behavior can either be fixed, be manually adjustable or adaptive from the control unit ( 3 ) are activated automatically.

Claims (14)

Device for controlling a ventilator, which has at least one sensor for detecting a ventilation parameter and at least one controller for presetting a control value, which is connected to a sequence control, characterized in that the sequence control ( 10 ) temporally alternating measuring phases and control phases and that the controller ( 8th ) is formed as part of a real-time control. Apparatus according to claim 1, characterized in that the ventilator ( 1 ) is designed as an emergency ventilator. Apparatus according to claim 1 or 2, characterized in that the ventilator ( 1 ) in the area of a transport case ( 2 ) is arranged. Device according to one of claims 1 to 3, characterized in that the flow control ( 10 ) specifies the measuring phases in periodically recurring time intervals. Device according to one of claims 1 to 3, characterized that the time interval of measuring phases dependent on of at least one metrological detected Parameter is specified. Device according to one of claims 1 to 5, characterized that during the execution a measuring phase disables a control module and activates a control module is. Device according to one of claims 1 to 6, characterized that the Control for processing a history-based actuator control signal is trained. Device according to one of claims 1 to 7, characterized that on a measuring phase a Number of n control phases with n> 1 are predetermined. Device according to one of claims 1 to 8, characterized in that the controller ( 8th ) is designed to support bilevel ventilation. Device according to one of claims 1 to 9, characterized that at least temporarily a memory for recording at least one signal is activated. Device according to one of claims 1 to 10, characterized that one Arithmetic unit for determining at least one average time Control signal is used. Device according to one of claims 1 to 11, characterized in that the control unit ( 3 ) is designed to control at least one valve. Device according to one of claims 1 to 11, characterized in that the control unit ( 3 ) is designed to control at least one blower. Device according to one of claims 1 to 13, characterized in that the control unit ( 3 ) is at least partially realized as a software.