HU202764B - Gas-mixing and feeding device of closed system particularly for producing nitrous oxide- oxygen gas mixture applied for assuaging of pains - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates to a mixture of dinitrogen oxide gas and oxygen gas, such that a constant max. Adds 75% dinitrogen oxide. The mixture is stored at a pressure of 5 KPa in a rubber ball (12) and dispensed as required by a suction valve (13). Aballon refills automatically. In the case of oxygen deficiency, its function is automatically eliminated by the built-in oxygen monitor (15) (Figure 1). Scope of description: Page 3, Figure 2 EN 202 764 B -1-

Description

FIELD OF THE INVENTION The present invention relates to a closed-circuit gas mixing and dispensing device for producing a nitrous oxide gas mixture used in medical practice for the relief of childbirth and accident pains, the dinitrogen oxide content of which may be varied from 0% to 75%. The gas mixing and dosing apparatus consists of symmetrically arranged systems, mixing, storage and dosing elements, connected to the outlet of the gases to be mixed, controlling the pressure and volume of the gases. The gas mixture is stored until use and metered through a patient-controlled breathing valve.

It is known that, in the medical field, in particular, the use of nitrous oxide gas mixture is increasingly used to relieve childbirth and accidental pain. In practice, two solutions are known. According to one known method, the gas mixture is produced and bottled at the site of the component manufacturing plants. The gas mixture thus formed is generally composed of 50% nitric oxide and 50% oxygen.

A disadvantage of the method is that the gas mixture, which is not always applicable to the degree of pain in childbirth and accident and to the individual sensitivity of the 25 patients, is not used, since the composition of the gas mixture cannot be changed during use.

Known in the medical art as a place of use, a mixing and dispensing device for use in the art is described in issue 25 of the "Medical Weekly" in 1969. The disadvantage of the described mixing and dispensing apparatus is that it can only be operated from gas cylinders, not from the central oxygen and nitric oxide installed in hospitals at 35 gas outlets. Its components are robust, difficult to handle and difficult to repair. The resulting gas mixture is stored at atmospheric pressure which makes it difficult to breathe with great force. 40

In medical practice, a small mixing and dispensing device has been found to be capable of varying the nitrous oxide content of the gas mixture from 0 to 75% according to the needs and sensitivity of the patient and providing 45 intermittent consumption controlled at the point of collection.

It is an object of the present invention to overcome the drawbacks of the prior art and to provide a mixing device which prevents the gases from mixing outside the mixing chamber and substantially interfering with their pressure. The resulting gas mixture is stored under high pressure in a rubber canister and delivered via a breathing valve to the patient's needs. The specially designed breathing valve prevents the gas mixture from entering the atmosphere when not in use. In the event of a deficiency in the oxy- gen gene, the device stops working or is stopped. it does not allow the oxygen content of the mixture to fall below 25%.

The device according to the invention is based on the assessment that if the oxygen content is kept constant, the amount of nitric oxide is changed at 100 kPa, and a gas mixture is passed through a pressure reducer in a pressurized gas cylinder with a pressure valve of 5 kPa. Under a pressure drop of 65 kPa, a gas mixture of the desired amount and composition is obtained.

The invention thus relates to a gas mixing and dispensing apparatus for producing a variable mixture of nitrous oxide and oxygen gases comprising two symmetrically constructed gas volume and pressure control systems, mixing, storage and metering elements, which are connected via a pressure reducer to the point where the gases are mixed. The gas volume and pressure control systems are connected to the gas extraction points via pressure reducers providing 100 kPa pressure. Safety valves are installed behind the pressure reducer to protect the gas volume and pressure control systems against overpressure. In the oxygen delivery system, the oxygen gas is maintained at 4 liters per minute by a constant flow element, while in the nitrous oxide gas delivery system, 075% of the gas is controlled by a variable flow element. The built-in oxygen monitor, which is controlled by the oxygen gas delivery system and connected to a permanent connection between the continuous flow and the flowmeter, prevents the addition of nitric oxide in the absence of oxygen. The pressure of the gases to be mixed can be checked by means of a pressure gauge and by a quantity gauge. The flowmeters are connected to the mixer via non-return valves, which are connected to a rubber cylinder placed in the net via a pressure regulator with a pressure of 5 kPa. The required gas mixture from the rubber cylinder is provided by the breathing valve.

The invention will now be described with reference to the drawings.

The attached drawings show

Figure 1 shows a schematic diagram of the device according to the invention, a

Figure 2 illustrates the structure of the pressure regulating member of the device, a

Figure 3 is a longitudinal sectional view of the breath valve, a

Figure 4 is a longitudinal sectional view of the oxygen guard.

The device can be connected to gas cylinders at a central gas supply pressure of 400 kPa or through a pressure relief device that reduces the pressure of oxygen and nitrous oxide gases by 400 kPara.

Further reduction of the gases to be mixed to 100 kPa is carried out by the pressure reducers 1 and 2. The pressure of the gases is indicated by the pressure gauges 18 and 19. The pressure reducers are designed to eliminate mechanical impurities present in the gases.

The nitrous oxide gas enters the mixing chamber 6 at a pressure of 100 kPa through a variable throttle 3 which adjusts the desired amount of gas through a rotameter 4 and a non-return valve 5. Here, it mixes with oxygen gas from the valve 7, the constant throttle element 8, the rotary meter 9, and the non-return valve 10, which provide the gas volume to the bile. Through constant throttling at 100 kPa, enough oxygen is introduced into the mixing chamber so that even with the maximum amount of nitrous oxide that can be adjusted, 25% oxygen is present in the mixture. From the mixing chamber, the gas mixture passes through a pressure reducer to a rubber cylinder placed in a mesh 12. The gas mixture pressure can be varied from 3 to 5 kPa for easier inhalation on the all pressure-2EN 202764Β. From the rubber cylinder placed in the mesh 12, the gas mixture can be inhaled through the breathing valve 13 via a rib hose and a respirator mask. The breathing valve is designed to be operated manually.

The A15 Oxygen Guard excludes nitrous oxide from the system in the event of a lack of oxygen.

The non-return valves 5 and 10 prevent the gases from mixing well outside the mixing chamber. The safety valves 16 and 17 built into the mixing gas system provide protection against overpressure of the device

Figure 2 is a sectional view of an embodiment of a pressure regulator all. The rubber membrane 28 and the variable tension spring 27 are connected via the transmission 29 to the spring 30 biased valve 30. The rubber diaphragm 28 maintains the valve 30 via the variable tension spring 27 through the transmission 29 against the spring 31 until the pressure in the space below the diaphragm exceeds the max. 5 kPa.

Figure 3 is a sectional view of the breathing valve 13 at rest. Through the orifice 26, the space below the rubber membrane 20 is approx. By providing a pressure drop of -0.5 kPa, the diaphragm opens the valve 23 closed by the spring 24 by means of a gear 21. The gas path connected to the inlet 25 is thus exposed to the outlet 26. Breathing valve 22 can also be manually operated. A pressure drop of -0.5 kPa is provided by the patient with a respiratory mask through the larynx.

Figure 4 is a sectional view of the oxygen guard. Nitric oxide bound to the inlet 37 is delivered to the constant throttle 8 through the outlet bias 38 via the valve 35 biased by the spring 36 when the pressure of the oxygen connected to the outlet 33 reaches or exceeds the min. 10 kPa.

Because of its advantageous properties, the gas mixing and dispensing device of the present invention can be effectively used in medical practice. Lung control of the device provides economical use of gas, since gas flow is created only during inhalation and in the amount corresponding to respiratory capacity.

The low pressure applied allows the use of plastic, glass and rubber. Due to the small parts that can be formed from these materials, their weight is lower than that of the previously used equipment. A special advantage is that the closed system only provides a gas mixture during breathing. In addition to economy, this also serves to protect the airspace.

Claims (4)

PATENT CLAIMS 1. A closed-circuit gas mixing and dosing device for producing a nitrous oxide gas mixture mainly used in medical practice for the relief of childbirth and accident pains, comprising symmetrically arranged systems for mixing, storing and dispensing gas pressure and volume control points. characterized in that a pressure regulator (2) for reducing the oxygen pressure to 100 kPa is connected to the gas collection point in the oxygen volume and pressure control system which, via a safety valve (17), is supplied via a continuous flow element (8) providing 4 l / min. by connecting a pressure gauge (19) and a volume gauge (9) to the mixing element (6) by means of a non-return valve (10), the pressure of the gaseous nitrogen oxide in the gas and nitrogen pressure control system A pressure regulator (1) reducing to 100 kPa is connected to a flow valve (3) which can be varied between 0 and 75% of nitric oxide via a safety valve (16), the flow rate being controlled by an oxygen guard (15) through a flow meter (4) with a non-return valve (5) is connected to the mixing element (6), the control of the oxygen monitor (15) in the oxygen pressure control system is connected to a pipeline connecting the constant flow (8) and the flowmeter (8), the pressure regulator (6) 11) is connected via a rubber cylinder (12) located in the net, where the intermittent gas discharge is provided by a breathing valve (13). Device according to Claim 1, characterized in that, in the pressure regulator connected to the mixing chamber, the rubber membrane (28) is connected to the valve (30) biased by a spring (31) via a gear (29) via a variable tension spring (27). Apparatus according to claim 1, characterized in that the rubber membrane (20) of the breather valve for intermittent gas extraction is connected via a gear (21) to a biasing valve (23) through a gear (21), under a pressure drop, a valve (22) fixed to the rubber membrane for manual operation is integrated in the breathing valve. Apparatus according to claim 1, characterized in that the oxygen membrane (34) controlled by oxygen pressure in the oxygen monitor is biased by a valve (35) between the inlet (37) and the outlet (38) of nitric oxide by a variable tension spring (36). is related.