SE446064B - CLINICAL USE RESPIRATOR DEVICE - Google Patents

Description

15 20 25 30 35 40 s1os77eé2 In the same way, advice or alarm conditions can be obtained when certain absolute values are exceeded or variations occur.

; In short, the possibilities for the respirator controlled by the microprocessor are practically unlimited, as is its control program, which eliminates the continuous monitoring of the operator, as is required with conventional respirators.

The invention will be further elucidated below in the form of an exemplary embodiment in connection with the drawing. In the drawing, the manifolds 2, 3 and 4, which contain nitrogen dioxide, oxygen and compressed air, respectively, are provided with corresponding pressure switches 18, 19a, 19b, a hand-operated pressure reducing device 20 connected to all the manifolds, which reducing device gives a reference pressure for the operation of the pressure equalizer 21. This pressure equalizer or pressure rectifier 21, which is pneumatically operated, as previously mentioned, guarantees that the pressure of the two gases to be mixed, oxygen and air or oxygen and nitrogen protoxide, are the same.

The pressure rectifier 21 communicates with the mixing chamber ZZ through the corresponding valve 23 to give air / N20 and the valve 24 to give O2, which valves have the same resistance. The mixing chamber 22 allows the homogenization of the gas mixture and serves as a reduction reserve for the variations in pressure in the supply to the inhalation valve 7. The filling of the mixing chamber 22 is controlled by the very sensitive double pressure switch 26, which acts on different valves in the mixer. Likewise, a safety valve 27 is incorporated, which ensures that the operating pressure of the mixing chamber 22 will in no case be exceeded. In addition, there is an O 2 analyzer 28 which, via the valve 29 and its associated pressure 30, allows the sampling of the gas, which The supply of the proportions of gas to the gas mixture to be supplied to the patient, the regulation of the composition and pressure thereof, takes place by means of a gas mixer. valves and the mixing sensor. The gas mixer makes the air / SYT8aS or SYrg & S / nitrogen (02 / N20) mixture of the corresponding gases under pressure which reaches it through the manifolds, the process utilized suitably being the control of the relative number of times each gas passes through the same fixed resistor.

In this respect, it should be pointed out that a suitable embodiment uses a time-controlled mixer which is described, for example, in the Spanish utility pattern 231,608. 10 20 25 30 35 40 8105776-2 The mixing chamber serves as a gas accumulator, so that increased, instantaneous flows are achieved in addition to allowing the homogenization of the gas mixture.

Extending from the mixing chamber is a manifold which reaches a battery of valves which constitutes the inhalation valve device. This inhalation valve includes the maintenance of the servo system that regulates the inhalation rate of the patient, depending on the signal transmitted to it by the flow meter and on the instantaneous values required at any given moment. The practical realization of this feed or inhalation valve is, as mentioned above, a battery of valves which are digitally stepped. Inserted in the manifold that supplies the gas mixture to the patient is a flow sensor, an element that permanently delivers information to the general control module. This sensor has a bi-directional character, low charge loss and a fast response.

The exhalation valve consists of a pneumatically operated diaphragm valve. The choice of the pneumatic control system is preferable due to its simplicity, reliability and low weight.

The pneumatic control of the exhalation provides the pneumatic signals for controlling the exhalation valve, depending on the electrical signals obtained from the general control module. It uses oxygen or compressed air as a compressed air supply.

The system for measuring the patient's pressure consists of a pressure sensor and an electrically controlled three-way valve, which allows the sensor to be periodically brought into contact with the surrounding atmosphere to automatically measure it.

Finally, there are various elements, such as pressure switches, filters and one-way safety valves, which act as extra measuring, controlling and safety elements.

With respect to the control module, it can be said that it monitors all the elements of the system depending on the input signals so that the required functions, which are programmed in the memories therein, are performed.

As a main element, there is an eight-bit microprocessor provided with its corresponding RAM and ROM memory blocks, as well as its various connected circuits, such as output input units, drive stages and so on.

The programs that regulate and control the operation of the device are structured as clearly limited function blocks, so that the writing of the programs is facilitated. The flexibility of the microprocessor is utilized as much as possible in this way and at the same time the possibilities of including new functions at a later occasion or the adaptation of the existing functions to specific needs in special applications are maintained.

For the introduction into the microprocessor of digital data and controls, there is a keyboard, which in a preferred embodiment of the respirator includes keys for speech, keys for the introduction of parameters and keys for the selection of various functions.

The microprocessor includes various routines for verifying parameters, representing the value of input data, both in terms of number and combination thereof, and for the absolute values of the input digital data, circumstances that minimize the possibility of improper use of the respirator.

Furthermore, the respective representation programs for representation on a cathode ray screen for various information, both alphanumeric and graphic, are included, which facilitates and gives the respirator a great deal of versatility.

The microprocessor's capacity to perform arithmetic operations makes it possible to calculate the following parameters and variables: Maximum exhalation pressure, resistance, volume correction, exhalation pressure, representation of curves, etc.

Furthermore, the on-screen respirator can display the curves that would result from the application of new breathing conditions to the patient being treated. This simulation can be accomplished while continuing the ventilation or respiration with those previously contained in the mixing chamber 22, analyzing it and thereby verifying the corresponding function of the mixer.

The measurement of this oxygen analyzer 28 can be verified and corrected by shutting off the gas passage from the mixing chamber 22 and by allowing the necessary time to elapse so that the gas present in the measuring chamber is only air. In addition to the mixing chamber 22, the inhalation valve 7 also communicates with the flow sensor 15 in the patient block, which instantaneous flow sensor is direction-dependent and placed close to the patient in the part that is common for inhalation and exhalation.

This sensor JS is collected in a block 31, which influences the signal emitted by the sensor IS through the line 32 and outputs this to the general control module 6.

A pressure sensor 11 is also connected to the patient circuit via a three-way valve 33, which structure allows it to communicate with the environment to verify and correct deviations from the corresponding 0-scale. L I t fi anà fi ngswnmilæl 14 is pneumatically controlled and can be closed completely or partially, a fact which allows the generation of continuous positive pressures during the exhalation phase. This valve 14: is controlled by a battery of misting valves which control the final pressure, which allows the generation of a variable pressure which controls the block, which is applied to the control of the valve 17 and causes the closing or the desired pressure in the patient circuit.

All these elements are controlled by the general control block 6, which comprises a microprocessor 35, preferably with eight bits, which communicates via various bus lines for this purpose with the remaining elements in the control module, including block or ROM storage memory 36 and block or RAM storage memory 37.

Data, controls and functions are introduced via the keyboard 38, which is connected to the microprocessor 35 through a corresponding interphase and coding unit 39, while the visible representation of the alphanumeric or graphical information takes place on a cathode ray tube 40 connected to the microprocessor system by the corresponding screen drive 41.

Blocks 42, 43 and 44 correspond to amplification blocks and analog digital converters which receive signals from the signal processor 31 for the flow sensor 15, from the pressure sensor 11 and from the oxygen analyzer 28, respectively, the signals from the various sensors in the respirator reaching block 45, which includes a plurality of level vectors. 46, 47, 48 and 49 comprise output phases via optocouplers and amplifiers for the signals coming from the control block, the outputs of these blocks being connected to and controlling the operation of the respirator, refer to the means by which the output block 49 is reserved for transmitting signals to the other operating elements with less functional weight. From this diagram of the general control block the supply has been eliminated, which under normal conditions is connected to the electrical network, whereby electric batteries are also present, which can guarantee the automatic function of the device for a certain period of time in the absence of electricity via the electricity network.

Thus, a program-controlled respirator is obtained which can perform functions within a large area and with several different methods of operation, which makes the human operator and continuous monitor, which are currently required in devices of this kind, superfluous.

Claims (10)

8105776-2 A device in a respirator for clinical use, characterized in that the respirator consists of a pneumatic module and a control module (6), cooperatingly connected to each other, the pneumatic module comprising elements for connecting to supply lines (Q, 3gU decompressed gases, which reach a pneumatically operated pressure equalizer (21), which is connected to a mixing chamber (22) controlled by a double pressure switch (26), from which the mixing chamber (22) emits two manifolds, which supply sets of valves with series-connected throttles, a set (17) of valves constituting an inhalation valve device, while a second set (16) constitutes a control valve device for an exhalation valve, the inhalation valve device feeding a patient circuit and comprising a flow sensor (13 wherein the control module is connected to the pneumatics module means by means of and control lines, and the control module is constituted by a microprocessor (35) provided with a keyboard (38) for entering data and instructions and a cathode ray screen (40) capable of simultaneously representing alphanumeric and graphical information, the keyboard (38) and the screen (40) being connected to the microprocessor (35) by corresponding interface units (39,41) therefor, the information lines connecting the control module to the pneumatics module reaching a plurality of understanding block carriers (42-44) followed by corresponding analog-to-digital converters, all connected to the bus compression lines of the microprocessor, which data bus lines also are connected to optocouplers and amplifiers, which provide signals capable of controlling the various valves and elements of the pneumatic module. Device according to claim 1, characterized in that the pneumatic module is provided with a pressure sensor (11) connected to the patient circuit through a three-way valve (33), one of the paths communicating with the ambient pressure and the valve being controlled by the control module (6) to allow periodic and automatic measuring with the pressure sensor. Device according to claim 1, characterized in that the control module (0) receives an information line coming from an oxygen analyzer (28), which is connected via a valve and its corresponding restriction to the mixing chamber (ZZ), the control module (0) comprising a program for evaluation and analysis of the function of the gas mixer so that periodic and automatic 8105776-2 auto-measurement is obtained. A device according to claim 1, characterized in that the flàkßavkünwren US) is a spring direction type and placed close to the patient in the inhalation and exhalation common part and emits a signal to a conversion block (32) which is connected to an information line for the control module. Device according to claim I, characterized in that the stynmxmlüx (6) has stored in a memory a program which enables the respirator to work in all the possible assisted and controlled breathing modes, as well as variations and combinations thereof. Device according to any one of claims I or 5, characterized in that the control module has registered in a memory a program for simulating the response obtained in the clinical variables for the patient as a result of the change of the controlled operating parameters, at this moment , by the respirator and what response simulation is obtained on the cathode ray screen without causing any variation in the actual operating parameters. 7.; Device according to any one of claims 1,5 or 6, characterized in that the cathode ray screen presents in the form of stable curves the curves corresponding to pressure, volume and instantaneous flow, which relative data are temporarily stored in a memory controlled by the operator independent of the screen. Device according to any one of claims 1,5,6 or 7, § - characterized in that the control module has a specific memory zone for accumulating the various clinical parameters for the patient during a certain period of time to form a database or clinical history for the patient. . 9. Device according to any one of claims 1,5,6,7 or 8, characterized in that the control module has registered in a memory a program which controls the keys of the keyboard, so that this must always be actuated in a defined sequence under simultaneous control. ~ of the proposed values following certain calculated patterns that do not allow proposed parameters, which could lead to incorrect combinations or abnormal values for the machine. Device according to one of Claims 1, S, 6, 7 or 8, characterized in that the control module has permanently registered in a memory certain basic operating parameters, which the equipment proposes to the operator at the initial moment of its connection.