DE212020000536U1 - oxygen blending system - Google Patents

Abstract

An oxygen blending system comprising an oxygen control module, an oxygen blending module connected to the oxygen control module, an evacuation device;
wherein the oxygen control module comprises an oxygen seat communicating with an oxygen control valve and connected to the oxygen blending module through the oxygen control valve;
wherein the purge means encases an interface on the oxygen control module and is provided with a gas guide hole;
wherein the oxygen mixing module comprises an oxygen mixing chamber in which a blower is provided, the oxygen mixing module being provided with an air inlet port and an oxygen inlet port connected to the oxygen seat; wherein the oxygen inlet opening is connected to the oxygen mixing chamber via an oxygen duct and the air inlet opening is connected to the oxygen mixing chamber via an air duct, and wherein the oxygen mixing chamber is connected to a transport duct.

Description

TECHNICAL AREA

The invention relates to an apparatus in the technical field of a heating and humidifying breathing apparatus, particularly relates to an oxygen mixing system.

STATE OF THE ART

In the field of breathing apparatus, the present state of the art has two structures - manual adjustment and automatic adjustment - for oxygen blending devices. Manual adjustment involves finding, by reference to an adjustment table, a target oxygen delivery flow rate which is assigned a total output flow rate. The rotary knob of the buoy flow meter is adjusted in such a way that the displayed value reaches the target value. After a period of waiting, the oxygen concentration displayed by the machine is read and determines whether the target value is being met. If there is a discrepancy, it will be adjusted. This adjustment method takes a long time to wait, and the margin of error from the target oxygen concentration is relatively large. An automatic adjustment involves adding a ratio valve to the high voltage oxygen input. According to the designed oxygen concentration and flow rate, a controller regulates the degree of opening of the ratio valve and monitors the target oxygen concentration in real time.

By comparing the above two oxygen adjustment methods, it can be seen that the automatic control structure is more intelligent and also easier to operate and use in actual clinical situations. From the prior art, it can be found that a present connection method and switching device are disadvantageous in that they are not easy to operate and difficult to assemble and disassemble, the manufacturing processes of which are complicated and difficult. In practice, the high voltage oxygen source is introduced into the air inlet port of the oxygen module as the oxygen source. The oxygen control module is placed outside. But its assembly structure is complicated, the oxygen mixing path is lengthened, it leads to untimely reaction speed.

In a patent document CN205759083U there are multiple articulation points in the component connection of the adjustment device, all of which are mechanically connected. But in use, all of these joints are at risk of oxygen leakage. There are a number of electrically controlled components within the machine and connectors are all exposed within the machine. If a leak occurs, all of the oxygen will be smuggled into the machine, leading to a major safety risk for the machine.

DISCLOSURE OF THE INVENTION

In view of the foregoing technical problem, the present invention provides a novel oxygen mixing system which is convenient to operate, easy to change, simple in manufacturing process during practical manufacture, and has high stability.

In order to achieve the above object, the technical solution of the present invention is: an oxygen mixing system comprising an oxygen control module, an oxygen mixing module connected to the oxygen control module, a purge device;
the oxygen control module includes an oxygen seat communicating with an oxygen control valve and connected to the oxygen blending module through the oxygen control valve;
the evacuation device encloses an interface on the oxygen control module and is provided with a gas guide hole that can discharge gas leakage inside the evacuation device to the outside;
the oxygen mixing module includes an oxygen mixing chamber in which a blower is provided, the oxygen mixing module being provided with an air inlet port and an oxygen inlet port connected to the oxygen seat; the oxygen inlet opening is connected to the oxygen mixing chamber via an oxygen duct, the air inlet opening is connected to the oxygen mixing chamber via an air duct, the oxygen mixing chamber is connected to a transport duct.

Furthermore, the oxygen seat is connected to the oxygen mixing module by a gas tube, with an oxygen control valve being provided between the oxygen seat and the gas tube by a pneumatic connection. In practice, during the prevention of a single failure, if leakage occurs at any of the above connection nodes, it will be evacuated by the evacuation device to the outside of the oxygen blending system, thereby preventing the release of oxygen to the inside of the breathing apparatus in the event of oxygen leakage as well as the risk can be prevented as far as possible.

Furthermore, an oxygen inlet is provided on a wall of the oxygen mixing chamber in the vicinity of an inlet side of the blower and is connected to the oxygen inlet port through an oxygen duct provided at the bottom of the oxygen mixing chamber.

Furthermore, to increase the reliability of the system, the oxygen control module is connected to the oxygen blending module by a pressure plate.

Furthermore, the oxygen control module also includes a control circuit board for detecting corresponding parameters.

Furthermore, the oxygen passage and the air passage of the oxygen mixing module are sealed by a sealing soft body and a cover plate to ensure that gas flows in a fixed passage.

A bypass sensor is also provided in the transport channel. A gas fan outlet is connected to a transport gas path. The bypass sensor is connected to the transport gas path by a transport tube. At the same time, the bypass sensor is connected to an oxygen mixing body through the transport tube. The bypass sensor detects corresponding parameters of an emitted gas.

Furthermore, a gas resistance measuring device is provided in the transport channel in order to sense a flow rate and a pressure of a gas, so that a target value can be controlled.

As another optimal configuration, the oxygen control valve is attached to the oxygen seat. The evacuation device encloses the oxygen seat and the oxygen control valve on the outside. Preferably, one interface of the purge means is sealed to an oxygen interface and another interface communicates with the oxygen blending module. A safety check against leakage for the entire oxygen control module is thus made possible.

The working principle of the present invention is: The oxygen O ₂ enters the oxygen inlet port at the bottom of the oxygen mixing body, enters the oxygen channel, and enters the oxygen mixing chamber through the oxygen inlet. The oxygen inlet is provided near the inlet side of the blower. Likewise, the air flow path means that the air enters the air inlet opening on the oxygen mixing body, through the air duct, through the air inlet of the oxygen mixing chamber and into the oxygen mixing chamber. The control board is provided in the oxygen control module to acquire related parameters. Due to the fan provided in the oxygen mixing chamber, the air outlet opening of the fan opens into the outlet of the transport channel and is structurally connected to the breathing apparatus. A target mixed gas is humidified and heated and supplied to a patient. Ie the work process of the whole machine is carried out. The mixed gas is supplied to the patient.

The present invention has the following advantageous effects: It is integrally assembled, easily manufactured, the structure of which is actually used during production with a simple manufacturing process, and the rate of finished products is high. In the present invention, a safe technical solution to the oxygen leakage is adopted, thereby increasing the stability of the system.

character list

• 1 12 shows a stereogram of an oxygen mixing system according to an embodiment of the present invention;
• 2 Fig. 12 shows a schematic representation of the structure of an oxygen control module according to an embodiment of the present invention;
• 3 Fig. 14 is a plan view of an oxygen mixing system according to an embodiment of the present invention (some parts of its structure are omitted);
• 4 Fig. 12 shows a schematic stereogram of the bottom of an oxygen mixing system according to an embodiment of the present invention (some parts of its structure are omitted);
• 5 12 shows a partial sectional view of an oxygen blending system according to an embodiment of the present invention;
• 6 FIG. 12 is a schematic diagram showing the structure of another oxygen control module according to an embodiment of the present invention.

EMBODIMENTS OF THE INVENTION

To facilitate understanding by those skilled in the art, the present invention is further illustrated with embodiments and figures as follows.

As in 1 shown, it relates to a stereogram of an oxygen blending system 11. The oxygen blending system 11 is provided with an oxygen control module 11-1, an oxygen blending module 11-2 Mistake. The oxygen control module 11-1 comprises an oxygen interface 110, an oxygen seat 111, an oxygen control valve 112, a purge device 113, which are connected in series. The oxygen interface 110 communicates with an oxygen connection pipe on the wall of the oxygen seat 111 and discharges the oxygen O ₂ into the oxygen control module 11-1. The oxygen seat 111 communicates with the oxygen control valve 112 which regulates the opening of its internal valve seat until a target value is reached. The oxygen control module 11-1 is connected to the oxygen mixing module 11-2, conveys the discharged oxygen to an oxygen mixing chamber 1148. Inside the oxygen mixing chamber 1148, a blower is provided.

As in 2 shown, it relates to a schematic representation of a structural connection of the oxygen control module 11-1 without the purge device 113. The oxygen seat 111 and the oxygen control valve 112 are connected by means of a pneumatic connection 122. The oxygen control valve 112 uses the pneumatic connector 122 to connect a gas tube 123 and thus connects to the oxygen blending module 11-2. In practice, during the prevention of a single failure, if leakage occurs at any of the above connection nodes, it will be detected by the in 1 shown exhaust device 113 is discharged to the outside of the machine, thereby preventing the release of oxygen to the inside of the machine in the event of oxygen leakage and the generation of risks to the greatest extent.

In the oxygen mixing system 11, as in 3 As shown, an oxygen inlet 1141 is provided in the vicinity of the engine air intake port at the bottom of the oxygen mixing chamber 114 . As in 4 As shown, an oxygen channel 1143 connected to the oxygen inlet 1141 is provided.

As in 4 and 5 As shown, the evacuator 113 is provided with a gas guide hole 1131 which connects with a gas guide groove 118 and can discharge leakage from any point inside the machine through the gas guide groove 118 to the outside of the machine and discharge into the air. The gas guide groove 118 can either be separately connected to the respirator housing or be considered a part of the respirator housing and serve as a passageway for discharging a leakage gas. As in 3 , 4 shown, the working principle of the oxygen mixing module, the flow path of oxygen and the flow path of air are specifically described. The oxygen control module 11-1 is connected by a pressure plate 126 to the engine's oxygen blending module 11-2. The oxygen O ₂ enters an oxygen through hole 1142 at the bottom of the oxygen mixing body 114 , the oxygen channel 1143 , and the oxygen inlet 1141 into the oxygen mixing chamber 1148 . The oxygen inlet 1141 is provided near the inlet side of the blower. Likewise, the air flow path is designed such that the air enters the air inlet opening 1146 on the oxygen mixing body 114, through the air channel 1145, through the air inlet 1147 of the oxygen mixing chamber and into the oxygen mixing chamber 1148. The control circuit board 115 is provided in the oxygen control module 11-1 in order to acquire corresponding parameters. Inside the oxygen mixing chamber 1148, the blower is provided to supply the mixed gas to the patient.

As in 5 1, the oxygen mixing module 11-2 is provided with an oxygen mixing body 114, an upper sealing soft body 117, an upper cover plate 116, a lower sealing soft body 125, a lower cover plate 124. They make a closed loop for the gas paths of the oxygen blending module and ensure that a gas flows along fixed paths. Inside the oxygen mixing chamber 1148 of the oxygen mixing body 114, the blower is provided to discharge the mixed gas introduced from the blower outlet 121 into an outlet 127 of the transport duct. The transport channel outlet 127 is in structural communication with the respirator. A target mixed gas is humidified and heated and supplied to a patient. Ie the work process of the whole machine is carried out.

As in 5 As shown, a bypass sensor 119 is provided in the transport channel, which is communicated through a first transport pipe 120 and a second transport pipe 129, respectively, to detect respective parameters of the discharged gas. A gas resistance measuring device 128 is provided in the transport channel in order to sense a flow rate and a pressure of a gas, so that a control of a target value is enabled.

As in 3 and 5 As shown, the oxygen-mixed gas is discharged through the blower outlet 121 and introduced into the transport gas path 1149, and supplied from the outlet 127 of the transport duct to the device outlet. A nozzle opening 1150 communicating with the first transport pipe 120 is provided on the transport gas path 1149, and another end of the first transport pipe 120 communicates with the inlet of the bypass sensor. The outlet of the bypass sensor is connected to the second transport pipe 129 .

As in 4 As shown, another end of the second transport pipe 129 communicates with a connection port 1151 of the oxygen mixing body 114, thereby performing the measuring action of the bypass sensor.

As in 2 As shown, the oxygen control valve 112 of the oxygen control module 11-2 is connected by a method through a gas pipe connector 122 according to its structure. For this connection node, the in 1 , 3 , 4 , 5 shown, corresponding derivations are carried out through the emptying device 113 to the outside of the machine.

As in 6 shown, it describes another embodiment of an oxygen control module. The use of the emptying device is explained in more detail. According to the structure of a gas control valve 130, it is attached to the oxygen seat 111 directly. Therefore, the purge device 113 externally wraps the oxygen seat 111 and the gas control valve 130 and is tightly fixed to the oxygen interface 110 . It is connected to the oxygen mixing module 11-2 at another end. A safety check against leakage is thus made possible for the entire oxygen control module 11-1.

The above embodiments only describe an oxygen mixing system. The structural form of its evacuation means is not limited thereby. Here, the emptying principle is mainly presented. Other connection methods also fall under the scope of this utility model. The description of the flow paths of the entire oxygen mixing system is only an illustration of one of the exemplary embodiments. All variations made according to the spirit of the invention and based on the technical solutions are intended to be included in the scope of the present invention.

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• CN 205759083 U [0004]

Claims (10)

An oxygen blending system comprising an oxygen control module, an oxygen blending module connected to the oxygen control module, an evacuation device; wherein the oxygen control module comprises an oxygen seat communicating with an oxygen control valve and connected to the oxygen blending module through the oxygen control valve; wherein the purge means encases an interface on the oxygen control module and is provided with a gas guide hole; wherein the oxygen mixing module comprises an oxygen mixing chamber in which a blower is provided, the oxygen mixing module being provided with an air inlet port and an oxygen inlet port connected to the oxygen seat; wherein the oxygen inlet opening is connected to the oxygen mixing chamber via an oxygen duct and the air inlet opening is connected to the oxygen mixing chamber via an air duct, and wherein the oxygen mixing chamber is connected to a transport duct. oxygen mixing system claim 1 , characterized in that the oxygen seat is connected to the oxygen mixing module by a gas tube, an oxygen control valve being provided between the oxygen seat and the gas tube by a pneumatic connection. oxygen mixing system claim 1 characterized in that an oxygen inlet is provided on a wall of the oxygen mixing chamber in the vicinity of an inlet side of the blower and is connected to the oxygen inlet port through an oxygen duct provided at the bottom of the oxygen mixing chamber. oxygen mixing system claim 1 , characterized in that the oxygen control module is connected to the oxygen mixing module by a pressure plate. oxygen mixing system claim 1 , characterized in that the oxygen channel and the air channel of the oxygen mixing module are sealed by a sealing soft body and a cover plate. oxygen mixing system claim 1 , characterized in that the oxygen control module further comprises a control board for detecting corresponding parameters. oxygen mixing system claim 1 , characterized in that a bypass sensor is provided in the transport duct, with a gas blower outlet being connected to a transport gas path, the bypass sensor being connected to the transport gas path through a transport pipe, and the bypass sensor being connected at the same time through the transport pipe to an oxygen mixing body connected. oxygen mixing system claim 1 or 7 , characterized in that a gas resistance measuring device is provided in the transport channel in order to sense a flow rate and a pressure of a gas, so that a control of a target value is made possible. oxygen mixing system claim 1 , characterized in that the oxygen control valve is attached to the oxygen seat, the evacuation means enclosing the outside of the oxygen seat and the oxygen control valve. oxygen mixing system claim 1 , characterized in that an interface of the evacuation device is sealed with an oxygen interface and another interface is in communication with the oxygen mixing module.

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