FR2596518A1 - Device for monitoring the pressure of a gas and portable respiration apparatus fitted with such a device - Google Patents

Abstract

Device for the monitoring the pressure of a gas, comprising means for conveying the gas to a manometer 2 with a needle 3, a sensor 5 placed on the angular trajectory of the needle 3 of the manometer 2 and means 10, 11 for processing the signal emitted by the sensor 5 during the passage of the needle 3. The device according to the invention is characterised in that the sensor 5 consists of a nozzle 7 connected to pneumatic supply means 6, and a dynamic pressure receiver 8 placed opposite the nozzle, a free space 17 being provided between the nozzle and the receiver in order to allow the passage of the needle 3 when the pressure of the gas conveyed to the manometer is greater than a determined adjustable value.

Description

DESCRIPTION
The present invention relates to a device for monitoring the pressure of a gas, comprising means for supplying the gas to a needle gauge, a sensor placed on the angular trajectory of the gauge needle and means for processing the signal emitted by the sensor when the needle passes.

 The invention also relates to a portable breathing apparatus using a device for monitoring the pressure of a gas of the type described above.

 Portable breathing apparatus is used in particular for the first aid given to the injured in road accidents. This type of device includes an alarm system in the event of a fault or in the event of ventilation stopping, for example when the respiratory mask is accidentally disconnected or during any other incident. For this, pressure is generally monitored at regular intervals. of the gas sent to the patient, by placing a sensor on the angular trajectory of the pressure gauge needle measuring the pressure of this gas. In known devices of this type, the sensor may have an optical, inductive or magnetic effect.

 When the sensor has an optical effect, this generates significant electrical consumption in order to maintain sufficient autonomy: the device must therefore carry a large battery, which increases its weight and increases its size.

 The inductive effect sensor has the drawback of requiring great precision in production, which makes it an expensive device, in particular when it is desired to produce portable devices with low colt.

 The magnetic effect sensor has the drawback of disturbing the movement of the pressure gauge needle, which presents a certain danger for the interpretation of the treatment carried out on the patient.

 The device according to the invention makes it possible to avoid these drawbacks. It is characterized in that the sensor consists of a nozzle connected to pneumatic supply means and a dynamic pressure receiver placed opposite the nozzle, a space being provided between the nozzle and the receiver to allow passage of the needle when the pressure of the gas supplied to the pressure gauge is greater than a predetermined adjustable value.

 Thus, the sensor placed on the angular path of the needle makes it possible to detect the passage of the latter. During this passage, the flow of gas flowing from the nozzle to the dynamic pressure receiver is temporarily interrupted, the sensor thus transmitting a signal to the corresponding processing means.

 In the application of the device according to the invention to portable breathing apparatus, the breathing gas sent to the patient is also sent to the pressure gauge in order to measure his pressure and thus cause the displacement of the needle: the position of the sensor is adjusted. so that in normal operating position, the needle passes into the space provided between the nozzle and the receiver during each breath of breathing gas. There is thus generally a first passage of the needle when the pressure increases and a second passage of the needle when the pressure decreases. It is possible at the level of the signal processing means emitted by the sensor to consider only one and / or the other of the needle passages.

 According to a preferred mode of # equalization, the sensor will be secured to a mobile collar around the dial of the pressure gauge making it possible to adjust the predetermined value of the pressure.

 Preferably, the means for processing the signal emitted by the sensor will include in particular means for resetting a time delay and an alarm, said means for resetting delivering a signal for resetting the time delay at each passage of the needle in the space provided in the sensor, said time delay delivering a signal whose amplitude is canceled out after a predetermined adjustable time interval, triggered by switching on the device, the cancellation of this signal triggering the activation of the alarm. In practice, such a time delay will be used, in a manner known per se, the charging and discharging of an electrical capacity or any electrical, pneumatic means, etc., ensuring the same function.

 The use of the device for monitoring the pressure of a gas according to the invention in a portable breathing apparatus is particularly advantageous since the supply of gas to the sensor can also be carried out by the storage means to generate a breathing gas to which this type of device is connected.

Thus, by way of example, the breathing apparatus according to the invention to which an oxygen cylinder is connected, will be able to operate only thanks to the presence of this oxygen under pressure.

 The alarm itself may be of the type activated by a pneumatic supply, but it is generally considered, in this type of device, that it is a consatinator of breathing gas, which is useless because it harms the autonomy of the device. This is why we generally prefer to provide an electronic type alarm, the electrical consumption of this type of alarm being low enough to allow the use of one or more electric batteries.

The invention will be better understood with the aid of the following examples of embodiments, given without limitation, together with the figures which represent FIG. 1, a schematic sectional view of a breathing apparatus according to the invention, FIG. 2, a schematic top view of the device of FIG. 1.

 The gas whose pressure is to be monitored is supplied by line 1 to the pressure gauge 2, known in itself provided with a rotary needle 3 which moves as a function of the pressure of the gas injected into the line 1. This pressure gauge 2 is fixed by two spacers 17 on the front face 16 of the breathing apparatus. Below the needle 3 is placed the dial 21 of the pressure gauge 2. Above the latter is placed a protective glass 23, fixed to a rotating dye 4. This is provided with an index 12 of identification of minimum pressure. The sensor 5 is integral with the rotating collar 4: it receives via the pipe 6 a pneumatic supply gas which is sent to the nozzle 7 opposite which is placed a dynamic pressure receiver 8 consisting of a simple nozzle extending by a pipe 9 connected to a pneumatic pressure sensor 10, the latter delivering an electrical signal to the electronic device 11, can; nandant the alarm 22. In FIG. 1, the sensor 5 has the form of a fork. Of course, this form can be any alone being necessary the presence of the nozzle 7 on the one hand, facing which is located the dynamic pressure receiver 8 on the other hand, a space 17 formed between these two elements allowing the passage of the needle 3 during the rotation thereof. This needle will preferably be of the "pallet" type, that is to say comprising a flat end portion 32, wider than that of the needle, an end whose width will be adapted to the diameter of the nozzle 7 and of the receiver. 8.

 The ventilation device according to the invention is also connected to an oxygen cylinder 24 connected, via the pipe 37 and the control valve 25 to the pipe 6, and on the other hand, by the pipe 27 to oxygen sequence injection means 26. The means 26, known per se, can be produced in entirely mechanical form, controlled primarily by the pressure of the oxygen (or of any other gas) contained in the bottle 24. These means 26 thus allowing the injection at regular intervals of the oxygen coming from the bottle 24 towards the nozzle 35 placed in the mouth or the nose of the patient, via the pipe 28, the non-return valve 29, the pipe 30 and the breathing mask 31 of inspiration-breathing linked to the patient. The means 24 designate both the gas bottle, the valve of this bottle and the regulator. A switch tap 38 is placed in the device according to the invention with a double function : setting "marc" he "of this switch valve 38 causes, on the one hand, the opening of a pneumatic valve which will allow the passage of gas in the pipes 27 and 37 and, on the other hand, the electrical powering of the device, including the means 11 and 22 as well as the teeporization. Also according to an embodiment known per se, the mask 31 ccworts a pipe 36 for patient exhalation, the access of which is locked by the valve 34, produced in the form of a balloon inflatable connected to the means 26, which allow the inflation of the balloon during the phase of insufflation of oxygen to the patient and the deflation of the balloon during the phase of exhalation of air by the patient, the latter being able to be rejected by the pipe 36, thanks to the presence of the non-return valve 29 in the pipe 30. The storage means (24) of respration gas, produced here in the form of an oxygen cylinder, are not part of the device according to the invention.

 The operation of the device according to the invention is as follows: when the breathing apparatus is started using the switch tap 38, the means 26 allow the injection of gas, such as aone, at regular intervals adjustable, in the pipe 28 to the patient, as well as through the pipe 1 to the pressure gauge 2, the needle 3 of which moves in rotation. If its angular displacement is sufficient, the needle 3 cuts off the gas beam coming from the nozzle 7 towards the receiver 8, which results in a sudden drop in pressure at the level of the pressure sensor 10. The electronic circuit 11 detects thus a variation of the electrical signal emitted by the sensor 10 (signal passing from logic level "1" to logic level "0" or vice-versa), the electronic circuit ll then generating the resetting of a time delay (recharging of a condenser) This tepporisation is triggered as soon as the appliance is started up by the switch tap 38, that is to say as soon as gas is blown into the pipe 1. If the needle 3 does not come to cut the jet of gas between the nozzle 7 and the receiver 8, no pressure variation is detected by the sensor 10. The electrical signal delivered by the time delay (discharge of the condenser) is canceled after an interval of time, adjustable, predetermined which triggers alarm 22, consisting of a if general intermittent light and / or sound

Claims (5)

 RE # NDICATIONS 1. Device for monitoring the pressure of a gas carrying means, (1) for supplying the gas to a needle gauge (2) (3), a sensor 5 placed on the angular path of the needle (3) the pressure gauge (2) and means for processing (10, 11) of the signal emitted by the sensor (5) during the passage of the needle (3), characterized in that the sensor (5) consists of '' a nozzle (7) connected to pneumatic supply means (6, 24 25) and a dynamic pressure receiver (8> placed facing the nozzle 7, a space (17) being provided between the nozzle (7) and the receiver (8), to allow passage of the needle (8) when the pressure of the gas supplied to the pressure gauge (2) is greater than a predetermined adjustable value.  2. Device according to claim 1, characterized in that the sensor (5) is integral with a flange (4) movable around the dial (21) of the pressure gauge (2), making it possible to adjust the predetermined value of the pressure.  3. Device according to claim 1 or 2, characterized in that the needle (3) of the handle (2) is of the pallet type, that is to say ccuporte an end (32) planar whose surface is adapted to the closing the dynamic pressure receiver (8).  4. Portable breathing apparatus ccwporting insufflation means (26) for periodically insufflating, in an adjustable manner, the breathing gas coming from storage means (24) towards the patient by means of a respiratory mask (31) , a sensor (5) placed on the angular path of the needle (3) of a pressure gauge (2) and means for processing (10,11,22) of the signal emitted by the sensor (5) during the passage of the needle (3), characterized in that the sensor (5) consists of a nozzle (7) connected to pneumatic supply means (24, 37, 25, 6) and a dynamic pressure receiver (8) placed facing the nozzle (7), a space (17) being provided between the nozzle (7) and the receiver (8) to allow the passage of the needle (3) when the pressure of the gas blown periodically into the patient, also brought to the pressure gauge, is greater than a predetermined adjustable value.  5. Apparatus according to the preceding claim, characterized in that the pneumatic supply means (6, 24, 25, 37) are connected to the storage means (24) to generate the breathing gas