NL8203470A - BREATHING DEVICE. - Google Patents

Description

b i | VO 3646

Subject: Ventilation equipment.

The invention relates to a respirator, which is provided with control devices for realizing many types of ventilations, which are built up from integrated parts and variants thereof and which comprise a time control system for the inspiratory and expiratory phase and an optical parameter. indication, in particular enable respiratory rate indication.

Characteristic of the known technical solutions:

In the recent ventilators, the ventilatory types can be controlled by integral respiratory systems, such as e.g. intermittent positive pressure ventilation (IPPV), also optionally supported by and in combination with a final exhalation overpressure (PEEP), continuous positive airway pressure functions during all phases of spontaneous breathing (CPAP), intermittent ventilation under 15 duress (IMV), also these optionally supported by respectively frequency-controlled. In addition, in the summary of these functions, other states (HFIIP / SOAP / NEEP / Sign function / Flow function, and both accelerated, delayed and constant) can be controlled and a variable limit value selection and a variable indication of 20 selected parameters is possible. .

It is characteristic of the many known ventilators that the operating cycle thereof comprises an inhalation phase and an exhalation phase. These are controlled either in the pressure cycle or in the time cycle. A module device can be provided for this.

Both phases are set in time control by separate time mechanisms, with an appropriate breath time ratio and an appropriate frequency. However, it is also possible that the frequency and the breathing time ratio are given in advance, so that corresponding inspiration and expiration times then occur (German patent specification 2,745,309).

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By fixed division of the operating cycle resp. the breathing period in inspiration phase and expiration phase, however, the optimal configuration of the ventilation characteristic is limited because within this split no sampling options for control signals for influencing adjusting devices are available and only interventions in the phases to a limited extent are made possible via expensive additional mechanisms. . The missing intervention option does not make it possible to target the volume or volume in any way. pressure course of the ventilation curve, while maintaining the same operating techniques, without varying objections. For example, e.g. introducing a pause between the normal inspiration and expiration phase can only be achieved by an additional delay circuit, which then shortens the effective inspiration or expiration time and thereby the output resp. reference conditions for the choice of pause 15 by the physician changes.

Also performing the IMV requires a separate time mechanism, which however can be used between breath periods to provide a spontaneous breath time section.

The frequency reduction method used in practice has drawbacks in that the transition from IPPV to IMV and vice versa is only possible with a relatively coarse staircase progression (German patent 2-7 ^ 6.92U), When, on the other hand, an end-expiratory pressure (PEEP) to be induced, one has to resort to a mechanically operating device, eg a PEEP valve, which closes the exhalation opening after the chosen pressure has been reached in the selected expiration phase.

However, the known devices undesirably increase the expiration resistance and often tend to develop vibration and noise (Anesthesia, 1977, Bd. 32, No. 2, pp. 138-1 ^ 7).

These objections are intended to be avoided in an automatic respirator by means of a control unit, which performs electronic controls and calculations, as well as pneumatic control and control for a series of the aforementioned types of ventilation (German patent 2.7 ^ 5 * 528). At the same time, this respiratory device 35 proposes a respiratory system with which a patient is supplied with a pressurized breathing gas stream, whereby sliders respond to control signals to control the gas flow to the patient for inhalation and exhalation. The electronic control serves to enable selection and setting of different 5 parameters t @. such as e.g. pressure, respiration rate, volume, etc. The pneumatic section of the control unit, on the other hand, performs various functions, in particular the pressure regulation of the inflowing gas and its control in the patient circuit.

-] _ q Controlling vital ventilation parameters such as e.g. deep breathing, breathing pause, positive and exhalation pressure (PEEP), continuous positive airway pressure (CPAP) and auxiliary functions require, in addition to a large number of electronic and pneumatic parts and connections, complex electronic units, 2.5 which are a logical sequence of closing and opening effect solenoid sliders. Finally, the processes for the automatic controlled inhalation are conducted via so-called comparators, the return of which, in a certain switching state, on the one hand produces the numerical representation of calculated breaths per minute, on the other hand, always a new conversion period and a new conversion period. initiates conversion cycle. It is established that the relatively expensive but controllable system solution allows the functions of the various types of ventilation and other states to be of satisfactory quality, but the structure of the circuit and more particularly the means by means of a number of solenoids Slider-built sequence circuits for comparison and time controls are complicated. Also with a program control and a valve control for time control, ventilation of any type can be realized in a suitable manner only by the use of expensive additional mechanisms (German patent specification 2.910.09 ^)

The object of the invention is to eliminate the above-mentioned drawbacks and to avoid expensive circuit construction. The invention further contemplates the greatest possible variability of the ventilation characteristic without expensive additional mechanisms at 12 0 3 4 7 0 .........

-h- provide simultaneous realization of meaningful boundary value formations for life-threatening parameter combinations and optical indications of selected parameters.

The object of the invention is to develop a ventilator control system built up from integrated switching chains, which within the resp. ventilation period has a number of removal possibilities, from which peripheral parts for controlling the volume resp. pressure development in the ventilation process can be controlled just as much as control modules for limit value formation 10 and optical indication.

To this end, the invention provides an electronic control device and a digital breath rate calculator, which are built up from integrated switching circuits and are connected to each other, the electronic control device being a time sequence control device consisting of 15 shift registers, which is provided with peripheral parts for controlling the volume resp. pressure development during the ventilation process and control modules for limit value formation for life dangerous parameter combinations, in which it is connected to the optical frequency indicating device 20 and in which the shift registers are arranged in such a manner that the shift registers are arranged in such a way that the proportions of the ventilation period sections occurring can be controlled in order to optimally configure the ventilation characteristic. and ventilation bellows can be realized by connecting flow and road valves.

In a preferred embodiment of the invention, the time sequence controller comprises four series bits of four bits connected in series, each consisting of a forward / backward counter of four bits and a binary 1-of-16 decoder with the shift registers of four bits each a 16-pole switch, connected on the one hand by two U-pole switches and two 3-bit shift registers of the same type with three flip-flops and solenoid valves arranged behind them, and on the other hand with a third 3-bit shift register of the same type for signals, the first two 35-bit shift registers on the one hand directly and on the other hand via an 8-pole switch with J 8203470 -5- connected to each other and with the shift register of U bits via a two-pole switch with a rectangle generator, two are fed even further via a frequency divider 1: 8 and / or a 3-pole switch.

A practical embodiment according to the invention is characterized in that the rectangular generator is connected to the pulse inputs of the shift registers of U-bits, which are connected to the third, starting pulses for the digital calculation via the outputs of the corresponding 16-pole switches. of the breath rate generating 3-bit shift register 10 for signals, which on the output side provide a time signal connection of the breath phase times t ^ to t ^ at the activation inputs of the shift registers of bits which have the rhythm of signaling frequency f via the U-pole switch and the flip-flops switch the solenoid valves.

Another embodiment consists in that the 16-pole switch on the output side, which is provided for the respiratory phase time, is connected to the signal line of an assistor and can be switched directly by means of an OR gate. Furthermore, the breathing gas side solenoid valves 20 connected to the first flip-flop and the second flip-flop can be connected in parallel via adjustable flow throttling devices.

In the respirator according to the invention, the digital respiratory rate calculator preferably consists of a calculation module with display unit, a shift register of U bits controlling the time information of the input information of the calculator and two further shift registers of 1+ bits intended for determining the respiratory period duration, two flip-flops to be used for establishing control and counting processes and ten for the logical supply of numbers and characters to the calculation module.

In the preferred embodiment of the respirator according to the invention, a special construction of the respiratory frequency calculator is obtained when the flip-flop connected to the electronic signal control device is connected to the pulse input of the first shift register of h bits at which the calculation frequency is f ^ is supplied, the outputs of the / 8203470-6 shift register except for the output connected to the R input of the flip-flop and the activation input of the shift register of U hits connecting to the poorten ports and through them with the calculation module, of which the outputs of this shift register of 5 H bits have an even further the S-input of the second flip-flop and another still further the R-input of the same flip-flop as well as the activation inputs of both , the breath period duration feeds determining shift registers of b bits and the one shift register of U bits at the pulse input of which pulses f supplied, with one output thereof 10 on the one hand influencing its activation input, on the other hand being connected to the pulse input of the other k bit shift register and the other terminals of the outputs of these two b bit shift registers via the AND gates and directly with the signal calculation module is connected, which is still connected to a signal generator and to the indicating device.

Preferably, the electronic control device resp. the time-sequence control device and the respiratory rate calculating device connected thereto for signals a compact unit, which is provided with a number of externally operable switching and adjusting means. According to the invention, a separate time selection of the respiratory period sections can be obtained with these operating elements present on a ventilator front plate, which are logically connected to the micro-switching circuits of the compact unit. This means that after the time t ^ has elapsed, the time t ^ begins, etc. until after the time t ^ has elapsed, the breathing period T has ended and the time t ^ has started again. By preparing the signals and the preselection of the control variants, the most diverse multiple phase ratios and volume resp. Pressure ventilation types are obtained, thereby improving breathability for the patient.

The invention will be explained in more detail below with reference to the drawing. In the drawing: Fig. 1 shows a detail view of the front plate of a respirator; FIG. 2 is a graphical representation of the multiple phase relationships 35 of some ventilation options; p / 820 3 4 70 ............................................ ...........................

FIG. 3 is a logical connection of integrated microcircuit circuits of an electronic controller at a ventilator as the first part of the total system; fig. 1+ a second part of the electronic control device connecting to the first part according to fig. 3, also in a logically connected representation; FIG. 5 is a first part of a digital breath rate calculator logically connected to the electronic control device of FIGS. 3 and b; and FIG. 6-a second part of the respiratory rate calculator connecting to the first part according to FIG. 5, also in a logically connected representation.

The respirator according to the invention is provided with an electronic control device 1 and a digital respiratory frequency calculator 2, both of which are built up from integrated micro-switching circuits and are suitably connected to each other. The control device 1 and the respiratory rate calculator 2 form a compact unit, which is provided with externally controllable switching and adjusting means, in order to enable the selection of the ventilation types and other states. The operating elements logically connected to the microswitch circuits of the compact unit are arranged on the front plate 3 shown in Fig. 1, which additionally comprises a digital frequency indicator k and a pressure indicating device 5 intended for airway pressure.

With the aid of the micro-switch circuits according to the invention, the compact unit has a number of removal options within the resp. ventilation period, from which peripheral components for controlling the volume or pressure development during the ventilation process can likewise be controlled as control modules for limit formation for life-threatening parameter combinations and optical indicators. The ventilator thereby realizes types of ventilation with an optimum configuration possibility of the ventilation characteristic and a distribution of the resp. ventilation period in time sections with the 35 postures vary. The signals generated across the switching circuits can

In accordance with the selected control variants in conjunction with flow and road valves, Jj * 8203470 -8- represent different multiple phase ratios, some of which are shown separately in Figure 2.

The realization takes place with the electronic control device according to FIGS. 3 and 1 (which is a time control device consisting of the shift registers 6, 7, 8 and 9 of 1+ bits. These four shift registers which can be set independently of each other consist of a forward / eight experiences counter of ij · bits and a binary 1-out 16-decoder. In addition, they are always connected to a 16-pole switch, which are marked with the references 10, 11, 12 and 13 on the one hand over two four-pole switches 1U, 15 and two 3-bit shift registers ΐβ, IT of the same type with three flip-flops 18, 19, 20 and solenoid valves 21, 22, 23 and behind them with a third shift register 2k of 3 bits of the same type 15 the first two shift registers 16, 17 are directly on the one hand and on the other hand via an 8-pole switch 25 and on the other hand the shift registers 6 to 9 are connected via a 2-pole switch 26 with a right corner generator 27, the shift registers 8, 9 of which are further fed over a frequency divider 28 with a division ratio of 1: 8 and / or a 3-pole switch 29.

The rectangle generator 27 is connected to the pulse inputs C of the shift registers 6 to 9, which are connected across the outputs of the 16-pole switches 10 to 13 to the shift register 2k for signals, which on the output side has a connection for time signal generation of the breath phase times t ^ to t ^ at the activation inputs 1 of the shift registers 6 to 9, which, in the rhythm of the signaling pulse frequency f ^, over the switches 1 ^, 15 and the flip-flops 18 to 20 have the solenoid valves 21 to 23 switch.

The 16-pole switch 13 30, which is intended for the respiratory phase time, is connected on the output side to the signal line of an assistor 30, which can be directly switched by means of an O-R port 31. Finally, the breathing gas side solenoid valves connected to the first flip-flop 18 and the second flip-flop 19 are connected in parallel over adjustable flow throttling devices 32, 33.

IM 35 The digital respiratory rate calculator 2 shown in FIGS. 5 and 6 consists of an arithmetic module 3l + with display unit 35, one controlling the time sequence of the account input signals of 1+ bits and two further ones. shift registers 37, 38 of 1+ bits intended for determining the breath period duration, two flip-flops 39, 1 + 0 and ten used for establishing the control and counting processes for the logical supply of numbers and characters ER gates 1 + 1 to 50 intended for the calculation module 3l +.

As can be seen from the depiction of the respiratory rate calculator, the flip-flop 29 connected to the electronic signal controller 10 is connected to the pulse input of the shift register 3β to which the calculation frequency f_ is applied. The outputs of this shift register 36, with the exception of an output connected to the R input of the flip-flop 39 and the activation input of the shift register 36, have a connection to the ER gates 15 + 1 to 50 and via this with the calculation module 3 + 1, of the outputs of this shift register 36 one further with the S input of the second flip-flop 1 + 0 and another even more with the R input of the same flip-flop 1 + 0 and the activation inputs of the two shift registers 37, 38 determining the breath period duration are connected. Finally, the shift register 38 is connected to the pulse input of which the pulses f are applied, with one output thereof connected on the one hand to the L activation input thereof and on the other hand connected to the pulse input of the other shift register 37, while the other terminals of the outputs of these two shift registers 37, 38 are connected via 25 the ER gates 1 + 1 + to 1 + 9 and directly to the signal calculation module 3I +, which is still in communication with a signal generator and with the indicating unit 35

Starting from the compact unit shown here and the logic circuit thereof, the breathing phase times t ^, t ^, t ^, t ^ of a breathing period T according to Fig. 2 are adjusted by means of the 16-pole switches 10 to 13 and the types of ventilation realized via switches 11 +, 15, 25, 26, 29 and the frequency divider 28 as well as the rectangular generator 27. When the ventilator is put into operation and applied to its operating voltage, the pulses f ^ occur on the pulse inputs of the shift registers.

8203470 -10-

At the same time, the 3-bit shift register automatically applies H ^ peak values to output 1, thereby activating shift register 6. The next pulse period brings its output A1 to H and sets the flip-flop 18 via the switch 1H. Thereby, the solenoid valve 21 is switched on and the inspiration time t ^ begins.

In the rhythm of the pulse frequency f ^, the next output is now switched. When the output signal reaches the output to which the switch 10 is connected, both the flip-flop 18 is reset and the shift register 7 is activated via the shift register 2h. This has the consequence that the solenoid valve 21 is switched off and the solenoid valve 22 is switched on via the flip-flop 19, so that the saving time t ^ and the inspiration time tg start. The further course in the shift registers 7 to 9 takes place analogously to that of the shift register 6.

When the shift register 8 is activated, the flip-flop 20 is set via the H-pole switch 15 and the solenoid valve 23 is switched on. From this moment the expiration time t ^ starts until the end of its running time, the solenoid valve 23 is closed again.

20 The expiration time t ^ follows, during which the solenoid valves 21 to 23 are closed. At the end of the expiration time t1, the shift register 6 is started again via the shift register 2h.

It has already been noted that the solenoid valves 21 and 22 on the respiratory phase side are connected in parallel via the adjustable current throttling devices 32, 33, so that, depending on the throttle position, it is possible to switch between accelerated and delayed volume flow during inhalation. When, on the other hand, the throttle 33 gpheel is closed, a pressure development with a final inspiration plate (PEB?) Is created during inspiration time tg.

When the switch 1U is switched over, the flip-flop 18 set by the shift register 6 is only reset by the shift register 7 at the end of the inspiration time tg. Therefore, the flip-flop 19 is not used and only the solenoid valve 21O is switched on during the total inspiration time t ^ and tg. As a result, the constant breathing gas flow is adjusted.

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In another position of the switch 1 ^, the flip-flops 18, 19 are simultaneously set by the shift register 6 at the beginning of the inspiration time t ^ and are reset only by the shift register 7 at the end of the inspiration time tg. This means that the two solenoid valves 21, 22 are open during the total inspiration time t ^ and tg. Deepened breathings are obtained by the parallel connection on the gas side, the ratio of which to normal breaths is set at the switch 25 and is realized in combination with the shift registers 16, IJ.

In the expiration times t ^ and t ^ the breathing gas profile can also be influenced. When e.g. If the expiration time t ^ compared to the expiration time t ^ is chosen to be small, an end-exhalation plateau (PEEP) is created.

For realizing an intermittent forced ventilation (IFV), the switches 15 and 29 are influenced such that at the beginning of the expiration time t ^ through the shift register 8 the flip-flops 18, 19 over the static inputs S thereof together with the flip-flop 20, therefore simultaneously, are set. The three flip-flops 18 to 20 are only reset by the shift register 9 at the end of the expiration time t ^ when the switch position set at the switch 13 is reached. During the total expiration times t ^ and t ^, the solenoid valves 21 to 23 are in the open position, so that a. spontaneous exhalation of the large amount of gas offered becomes possible. In order to extend the expiration times t ^ and t ^, the frequency divider is switched on with the switch 29, which reduces the pulse frequency f ^ for the shift registers 8, 9. This results in a time extension of the total expiration times t ^ and t ^ by eight times.

In a further switching stage of the switch 15, an operating condition can be provided, which makes it possible to switch immediately to inspiration in an attempted inhalation and to realize assisted ventilation. The operating condition of the electronic control device 1 is obtained by the switch 15 switching on the assistor 30, which starts the shift register 6 via the 0F gate 31 at any time during the total expiration time t ^ or t ^.

ί; r «t 1 8203470« -12-

This electronic control device 1, which is constructed as a time control device, is, as explained, compactly connected to the respiratory rate calculator 2, which, as also explained, essentially consists of the calculation module 3 with display unit 35, the shift register 36, which defines the time sequence of the input of the computer controls the two shift registers 37, 38 for determining the breathing period duration, the flip-flops 39, Πθ for establishing the control resp. counting processes and the AND gates Hl to 50 for logically entering numbers and characters. The links 10 then also show a connection of the digital outputs D1 to D10 via the AND gate H1 to 50 with the numerical and operating calculation inputs of the calculation module die, which divide the respiratory rate f ^ by the sum of 60 seconds. determines the respiratory phase times t ^ to t ^.

At the beginning of the inspiration time t ^, the flip-flop 39 is set by a starting pulse of the controller 1, which in turn turns on the shift register of Π bits. In the rhythm of the calculation frequency f_, the outputs A0 to A15 are now brought to the peak. As a result, at the H peak at the output A 1 via the AND gate H1, the second input of which is connected to the output D 6 of the calculation module 3Π, a "six" in the calculation module 3Π becomes introduced. At the H peak at the output A 3 of the shift register 36, the AND gate b2 supplies the first "zero" and also a second zero "at the H peak at the output A 5. If the input with the calculation frequency 25 fn is continued, then the signal A 7 introduces the operative character "division", followed by the two-position measurement of the respiratory phase times t ^ to t ^ with the signals A-9 and A 11. This measured value is determined by the shift registers 37, 38 of U bits acting as counter, because the pulses applied to the pulse input C of the shift register 38 until the shift register 38 is stopped by the Q signal of the flip-flop Ho The flip-flop Η-O is set at the H peak at the output A 9 of the shift register 36 since the reading of the measured value from the shift register 38 (tens) is currently started. of the shift register 36 causes the values to be supplied the shift register 37 (units).

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After the end of the value input and a now occurring H-peak at the output A 13 of the shift register 36, the heath shift registers 31, 38 as well as the flip-flop UO are reset, causing a new counting rhythm to start. In addition, the reset the operation mark "equals" is applied to the calculation module 31 through the AND gate 50. After this input and the calculated respiratory rate f ^, the indication thereof takes place in the indicating unit 35.

When the H-peak finally occurs at the output A 1H of the shift register 36, it is, like the flip-flop 39, fed through the 1 input 10 and 10 respectively. R input of its switching circuits reset. As a result, the respiratory rate calculator 2 is again able to receive the next starting pulse originating from the electronic control device 1.

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Claims (7)

1. Ventilation device, provided with control devices for the realization of many types of ventilations, which are built up from integrated parts and variants thereof and which have a time control system for the inspiration and expiration phase, as well as an optical paranitic indicating device, in particular a respiratory frequency indication. device, characterized by an electronic control device (1) and a digital breath rate calculator (2), which are built up from integrated circuit circuits and are connected to each other, the electronic control device (1) being a time sequence control device consisting of shift registers 10 peripheral elements for controlling the volume resp. pressure development during the breathing process and of control modules for limiting value formation of life-threatening parameter combinations are provided and connected to the digital frequency indicating device, whereby the shift registers are designed in such a way that arbitrary ratios are configured for controlling the ventilation types with optimal configuration possibilities of the ventilation characteristic. of the occurring ventilation period sections and ventilation courses can be realized by cross-linking with flow and road valves. Ventilation device according to claim 1, characterized in that the time-sequence controller is provided with four series-connected shift registers (6 to 9) of 1+ bits, each consisting of a forward / reverse counter of U bits and a binary 1-out -16 decoder, in which the shift registers (6 to 9) of U bits 25 are each connected to a 16-pole switch (10 to 13), which are connected on the one hand by two-pole switches (1 ^, 15) and two shift registers ( ΐβ, 17) of 3 bits of the same type with three flip-flops (18 to 20) and the solenoid valves (21 to 23) behind them, and on the other hand with a third shift register (2b) of 3 bits of the same type for signals are cross-linked, the first two 3-bit shift registers (16, 17) on the one hand directly on the other and on the other hand via an 8-pole switch (25) with each other and with the shift registers (6 to 9) of U bits over a 2-pole switch (26) are connected to a right angle generator (27) two of which (8, 9) are moreover! 8203470 f -15- are fed via a frequency divider (28) and / or a 3-pole switch (29). Ventilation device according to claims 1 and 2, characterized in that the rectangle generator (27) is connected to the pulse inputs of the 5 shift registers (6, 9) of U bits, which are connected via the outputs of the 16-pole switches (10 to 13) of which the third starting pulses for digitally calculating the breath rate-supplying shift register {2b) of 3 bits for signals are cross-linked, which shift register on the output side provides a connection for time signal-10 supplying the breath phase times (t t ^) at the activation input of the shift registers (6 to 9) of k bits, which, in the rhythm of the signaling pulse frequency across the U-pole switches (1U, 15) and the flip-flops (18 to 20), the solenoid valves (21 to 23). Ventilator according to Claims 1 to 3, characterized in that the 16-pole switch (13) serving the respiratory phase time (13) is connected on the output side to the signal conductor of an assistor (30) and is connected by means of an OR gate (3l) can be directly switched. Ventilation device according to claims 1-U, characterized in that the solenoid valves (21, 22) connected to the first flip-flop (18) and the second flip-flop (19) on adjustable breathing throttles (21) 32, 33) are connected in parallel. 6. Ventilation device according to claims 1-5, characterized in that the digital breath rate calculator (2) consists of a calculation module {3b) with display unit (35), a shift register (36) of b bits controlling the time sequence of the calculation input. and two further shift registers (37, 38. of b bits serving for determining the respiratory period duration), two flip-flops (39, U0) used for establishing the control and counting processes and ten for the logical input of digits and AND gates (Ui to 50) serving characters to the calculator. Ventilation device according to claim 6, characterized in that the flip-flop (39), which is cross-linked with the electronic control device (1) for signals, with the pulse input of the first sliding (jT j 35 yeast (36)) bit, to which the calculation frequency f ^ is applied, I-8203470 ê * -16- is connected, the outputs of which except one with the E input of the flip-flop (39) and the activation input of the shift register (36) of k hits cross-linked output comprise a connection to the EK gates (U1 to 50) and via this to the calculation module (3U), 5 of which from the outputs of this shift register (36) of U bits a still next to the S input of the second flip-flop (Uo) and another still next to the S-input of the same flip-flop (Uo) as well as the activation inputs of the two shift registers (37, 38) of the U bits determining the breathing period duration are fed and wherein the one h bit shift register (38) of pulses f1 fed to the pulse input with the one output ang thereof feeds its activation input on the one hand, and is connected on the other hand to the pulse input of the other shift register (37) of U bits and the other terminals of the outputs of these two shift registers (37, 38) of U bits via the 15 AND gates ( UU to U-9) and are directly linked to the signal calculation module (3U), which is still connected to a signal generator (51) and to the indicating unit (35). Ventilation device according to claims 1 to 7, characterized in that the electronic control device (i) and the respiratory rate calculator (2) cross-linked with it for signals form a compact unit, which is provided with a number of switching and adjusting means which can be operated from the outside . ^ 820 3 4 70