JPS63292965A - Peep apparatus in artificial respirator - Google Patents

Abstract

PURPOSE:To reduce the respiration work load of a patient to a large extent by effectively preventing the generation of the variation in PEEP pressure, by detecting the PEEP pressure and applying feedback control not only to the pressure of an inhalation circuit but also to that of an exhalation circuit corresponding to the detected PEEP pressure. CONSTITUTION:When the magnitude of actual PEEA pressure PA is equal to or more than objective PEEP pressure PT, the output voltage signals V1, V2 to electropneumatic converter 5, 7 are set to V2=0 and V1= K1XPT-K1'XDELTAP to lower the actual PEEP pressure PA. When the actual PEEP pressure PA is excessively lower than the objective PEEP pressure, difference pressure DELTAP is converted to an absolute value and, thereafter, said signals V1, V2 are set to V2=K2XDELTAP and V1=K1X(PT+DELTAP). As mentioned above, the electropneumatic converters 5, 7 are controlled while the actual PEEP pressure PA is compared with the objective PEEP pressure PA and the pressure (actual PEEP pressure PA) of a common circuit 1 is held to the objective PEEP pressure PA. Control gains K1, K1', K2 are preliminarily calculated by experiment.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a PEEP device in a ventilator.

(Prior Art) In a human respiratory system, an inhalation circuit and an exhalation circuit are connected to a common circuit connected to the patient's lungs. Humidity coming from this intake circuit? iJR of A adjustment and oxygen concentration
The conditioned air is supplied to the common circuit, ie, the patient's lungs, while the air, after being gas-converted by the patient's lungs, is exhausted from the common circuit to the outside through the exhalation circuit.

In such a ventilator, the capacity of each of the circuits described above is limited, resulting in resistance during breathing. i.e.
) If the mouths of the two people are open to the atmosphere, which has an infinite capacity, both breathing resistance and exhalation resistance effectively act as blades, but when a respirator is applied to the patient's mouth, the patient's Due to restrictions on the capacity of the mouth atmosphere,
The pressure within the circuit of the ventilator fluctuates as the patient breathes, resulting in a large increase in both inspiratory resistance and expiratory resistance.

For this reason, a device, usually called a PEEP device, is attached to the ventilator to keep the pressure in the common circuit at a predetermined constant pressure. In particular, to reduce the patient's respiratory tract, the pressure in the common circuit is generally reduced by the PEEP device.
The positive pressure is called EEP pressure and is slightly larger than atmospheric pressure.

This conventional PEEP device consists of an electrically controlled pressure regulator (e.g. an electro-pneumatic converter) connected to the inspiratory circuit and a manually operated pressure regulating valve (a type of variable aperture). Then, the expiratory circuit pressure v! is set at a predetermined position corresponding to a predetermined PEEP pressure! With the J valve adjusted manually, the PEEP pressure is maintained constant by adjusting the pressure in the intake circuit using a pressure regulator connected to the intake circuit.

(Problems to be Solved by the Invention) However, in the conventional PEEP device δ, the PEE
The P pressure fluctuated considerably, and therefore the reduction in the patient's work of breathing was not always fully satisfactory.

Therefore, an object of the present invention is to provide a PEEP device for a ventilator that can more effectively prevent PEEP fluctuations and significantly reduce the patient's work of breathing. .

(Means and operations for solving the problem) In order to achieve the above-mentioned object, the present invention detects the pressure in the common circuit, that is, the PEEP pressure, and the detected P
The pressures of both the inhalation circuit and the exhalation circuit are feedback-controlled in accordance with the EEP pressure. Specifically, the configuration is as follows. That is, the inspiratory circuit and the expiratory circuit are connected to a common circuit connected to the patient's lungs, and air is supplied from the inspiratory circuit to the common circuit.
In a ventilator that discharges air from a common circuit through an exhalation circuit, as shown in Figure 9, there is an inspiratory pressure adjustment means for adjusting the pressure in the inspiratory circuit, and an expiratory pressure adjustment means for adjusting the pressure in the exhalation circuit. With means.

PEEP pressure detection means for detecting the pressure of the common circuit; control means for receiving the output from the PEEP pressure detection means and controlling the inspiratory pressure adjustment means and the expiration pressure adjustment means so that the PEEP pressure becomes a predetermined constant pressure; This is a configuration equipped with the following.

As described above, in the present invention, by detecting PEEP pressure and feedback controlling not only the pressure in the inhalation circuit but also the pressure in the expiration circuit according to the detected PEEP pressure, fluctuations in the PEEP pressure can be minimized. It can be completely prevented.

(Example) Hereinafter, an example of the present invention will be described based on the attached drawings.

In Figure 1, 1 is a common circuit shaped like 7,
The confluence end 1a is connected to the patient's lungs H (generally connected airtightly to the patient's mouth via an adapter).
. Further, an inhalation circuit 2 is connected to one of the two branched ends 1b and lc, and an exhalation circuit 3 is connected to the other. This intake circuit 2 is connected to an air tank 4 as a pressure source, and the exhalation circuit 3 is open to the atmosphere.Of course, the above-mentioned tank 4 is subjected to humidity adjustment and oxygen concentration adjustment as is known. Air at a predetermined pressure is stored.

A first electropneumatic converter 5 (voltage-pneumatic converter) is connected to the intake circuit 2 as an intake pressure adjusting means.

Further, a tip nozzle 6a of an injection circuit 6 connected to the tank 4 is opened to the exhalation circuit 3, and a second electropneumatic converter 7 is connected to this injection circuit 6. It is oriented in the opposite direction to the flow direction of exhaled air flowing from the common circuit 1 toward the exhalation circuit 3, that is, the air injected from the nozzle 6a is oriented so as to flow toward the common circuit 1.

Reference numeral 8 in FIG. 1 is a control unit composed of a microcomputer, which basically includes a CPU, ROM, and RAM.
and PEEP pressure setting switch 10 are inputted, and the control unit 8 sends a voltage signal v corresponding to the pressure to each of the electropneumatic converters 5 and 7.
1 or v2 is output from the pressure sensor 9.

It detects the pressure in the common circuit 1, and outputs the detected pressure to the control unit 8 as a voltage signal FA. In addition, - the above switch IO can be set by manual operation.
It changes the EP pressure, that is, the target PEEP pressure,
The control unit 8 sends a voltage signal FT according to the target PEEP pressure.
Output to. In addition, in the embodiment, the switch IO is PEE
The P pressure can be set steplessly in the range of 5 cm to 20 cmH2O.

In the above configuration, the actual PEE of the common circuit l
The P pressure, that is, the pressure detected by the pressure sensor 9, can be changed by the following factors, assuming that the patient's breathing state is in a certain stopped state. That is, (1) By changing the pressure of the intake circuit 2, the larger the intake pressure is, the greater the actual PEEP pressure PA becomes. The intake pressure is adjusted by controlling the first electropneumatic converter 5.

(2) By changing the injection pressure (injection amount) from the nozzle 6a, the greater the injection pressure, the greater the exhalation resistance from the exhalation circuit 3, and the greater the actual PEEP pressure PA. The injection pressure is adjusted by controlling the second electropneumatic converter 8.

Next, the details of control by the control unit 8 will be explained with reference to the flowchart shown in FIG. Note that in the following explanation, S indicates a step.

First, in Sl, the target PEEPEEPT set by the switch 10 and the actual PEEP pressure PA of the common circuit 1 detected by the pressure sensor 9 are read.Next, in S2, PT is subtracted from FA to obtain the differential pressure ΔP.
is calculated. In S3, it is determined whether the differential pressure ΔP is greater than or equal to zero. If the determination in S3 is YES, the magnitude of the actual PEEP pressure PA is equal to the target PEEP F.
E P T or more, in this case, the electropneumatic converter 5
．． The output voltage signals Vl, V2 to 7 are set as 54 or S5, that is, in S4, V2=0 (no air supply from the intake circuit 2). Further, in S5, V1=KIXPT-Kl'XΔP is set.

Note that Kl and Kl' are control gains, respectively.In this way, the actual PEEP pressure PA is equal to the target PEEP
When the PEEP pressure is higher than the pressure FT, vl and v2 in S4 and S5 are set to lower the actual PEEP pressure PA.

After step S5, in step S6, Vl and V2 set as described above are output to the electropneumatic converter 5 or 7.

On the other hand, if the determination in S3 is NO, the actual PEEP
This is when the pressure PA is too smaller than the target PEEP pressure FT. In this case, first, ΔP is converted into an absolute value in S7, and then Vl and V2 are set in S8 and S9.
S6, 1-31. When Vl and v2 are output to the electro-pneumatic converter or 7 and pass through 37 to S9 of ζe, this is to thicken the actual PEEPJEPA, and V2= is set to 2XΔP.

It is set as V1 = KIX (FT+ΔP).

Note that K2 is a control gain.

In this way, the actual PEEP pressure PA is changed to the target PEEP pressure P.
By controlling the electropneumatic converters 5 and 7 while comparing with A, the pressure of the common circuit l (actual PEEP pressure PA) is set to the target P.
The EEP pressure is maintained at PA. Note that the control gain Kl,
, ', K2 may be determined in advance by experiment. Of course, this control gain is set in consideration of responsiveness so that no backflow of air occurs from the exhalation circuit 3 side to the inhalation circuit 2 side.

Figure 3 shows the effects of the PEEP device according to the present invention (7).
The test device used to obtain data for comparison with the PEEP device is shown. In addition, in this Figure 3,
Elements corresponding to those in FIG. 1 are indicated with the symbol "'".

First, 21 in Figure 3 is HARVA! ID APPAR
Called ATUS, it is a device that uses a type of cylinder device to artificially create a certain breathing state. This device 21 has a displacement of 500cc (one breath M
), a breathing rate of 20 breaths/min was artificially created. Further, 22 is a hot-wire type flow meter connected to the common circuit 1' to measure the actual respiration volume produced by the device 21. Furthermore, in order to check the fluctuation state of the PEEP pressure, the actual pressure of the common circuit 1' is
It was measured by the pressure sensor 23 connected to '. and,
P according to the present invention for the inhalation circuit 2' and the exhalation circuit 3'
Respiration volume v when this FEBP device is activated by connecting an EEP device or a conventional PEEP device (2 types)
and the actual PEEP pressure P and the P-V obtained from both.
I got a line diagram. More specifically, each signal from the flowmeter 22 and pressure sensor 23 is input to the microcomputer 24, and the display 25 displays the rPJ, rVJ, and rp-
v-diagram" is now displayed.

I would like to show the data (p-v line diagrams) obtained as described above. ), Figure 6(a), (
b) (Conventional device 2). In addition, each figure of the above (5L) shows the case when the target PEEP pressure is 5 cmH2O, and the above (5L).
Each figure in b) shows when the target PEEP pressure is 10 cmH2O.

Comparison of this figure 4 (a), figure 5 (a) and figure 6 (P
EEP pressure 5 cmH20), and comparison with Fig. 4(b), Fig. 5(b), Fig. 6(b) (PEEP pressure 10cmH
20), it is understood that the variation in PEEP pressure (P) of the present invention is extremely small compared to that of the conventional device, and as a result, the patient's work of breathing is significantly reduced (respiratory work The amount of work increases as the area surrounded by the PV diagram increases).

FIG. 7 shows the changes in PEEP)fP as well as the changes in respiration volume, with the horizontal axis being the parameter of time. (b
)), and (b) corresponds to the conventional device l (Fig. 5(a), (
(b) corresponds to), and (c) is the conventional one! ! 2 (Figure 6(a)
, (corresponding to (b)). As is clearer from FIG. 7, it is understood that in the present invention, PEEPEEP is maintained at a predetermined constant pressure with almost no fluctuation.

FIG. 8 shows another embodiment of the present invention, and the same components as those shown in FIG. 1 are given the same reference numerals and their explanations will be omitted.

In this embodiment, the injection circuit 6 and the second electro-pneumatic converter 7 connected thereto in FIG. 1 are eliminated, and instead the opening degree of the atmosphere-side open end 3c of the exhalation circuit 3 is adjusted. It is. That is, a valve body 15 that approaches and separates from the open end 3C is provided, and the position of this valve body is controlled by a driving means 16 such as a step motor or a linear motor.
In the case of this embodiment, the adjustment is made by
The pressure in the exhalation circuit 3 is adjusted by configuring a kind of variable diaphragm.In addition, this embodiment has the advantage that the amount of air used is smaller than that in FIG. There is.

Although the embodiment has been described above, a predetermined amount of air at a limited pressure is always supplied to the intake circuit 2 from the steady flow supply device 17 as shown by the dashed line in FIG. You can do it like this.

(Effect of the invention) As is clear from the above, the present invention
It is possible to almost completely eliminate pressure fluctuations and significantly reduce the patient's work of breathing.

[Brief explanation of drawings]

FIG. 1 is an overall system diagram showing one embodiment of the present invention. FIG. 2 is a flowchart showing a control example of the present invention. FIG. 3 is an overall system diagram showing a test device used to compare the effects of the present invention with conventional devices. FIG. 4(a) and FIG. 4(b) show P obtained by the present invention.
- A graph showing a V diagram. FIG. 5(a) and FIG. 5(b) are graphs showing PV diagrams obtained by a conventional device. FIGS. 6(a) and 6(b) are graphs showing PV diagrams obtained by another conventional device. FIG. 7 is a graph showing enlarged variations in the effect of PEEP pressure in the present invention and the conventional device. FIG. 8 is an overall system diagram showing another embodiment of the present invention. FIG. 9 is an overall configuration diagram of the present invention. H: Lungs (patient) l: Common circuit 2: Inspiratory circuit 3: Expiratory circuit 5: First electro-pneumatic converter (inspiratory pressure regulating means) 6: Injection circuit (expiratory pressure regulating means) 7: Second electro-pneumatic converter (expiratory pressure regulating means) Pressure adjustment means) 8: Control unit 9: Pressure sensor

Claims (1)

[Claims] (1) An inhalation circuit and an exhalation circuit are connected to a common circuit connected to the patient's lungs, and air is supplied from the inhalation circuit to the common circuit, while air from the common circuit is discharged from the exhalation circuit. In a ventilator, an inspiratory pressure adjusting means for adjusting the pressure in the inspiratory circuit, an expiratory pressure adjusting means for adjusting the pressure in the expiratory circuit, a PEEP pressure detecting means for detecting the pressure in the common circuit, and a A control means for receiving the output and controlling an inspiratory pressure regulating means and an expiratory pressure regulating means so that the PEEP pressure becomes a predetermined constant pressure.
EP device.