TR2021004544A2 - A flow sensor device - Google Patents

Abstract

The present invention is a housing (2) having an inlet (3), an outlet (4), and a flow channel (5) through which air flows following a central axis (I), and a flow meter that measures the amount of air passing through the air channel (5). It relates to a flow sensor device (1) comprising a sensor unit (6).

Description

DESCRIPTION A FLOW SENSOR DEVICE This invention relates to a flow sensor device, particularly a breathing support apparatus comprising a flow sensor Device. A flowmeter measures the amount of a gas or flow flowing through or around the flowmeter sensors. Flowmeter sensors work in different ways, but in a way that mirrors the target and provides the most precise and repeatable flow measurements for a given application. Flowmeters contain an inlet, an outlet, and a flow channel extending between the inlet and the outlet. A flow sensor unit measures the amount of airflow passing through the flow duct. The flow sensor unit measures the amount of airflow passing through the flow channel at a single point, which may cause fluctuations and inconsistencies in the measurements. One reason for this may be turbulence in the air flow due to the flow speed or the physical structure of the flow channel. An inlet with a smaller cross-section than the outlet cross-section causes a vortex in the flow channel, resulting in points where the pressure is measured higher or lower than the actual value. This results in unstable flowmeter measurements with fluctuations or irregular flow patterns. Even if flowmeters make accurate measurements, even more accurate measurements are required in applications such as breathing support apparatus, since a patient's life depends on it. In the state-of-the-art patent document numbered EP3048432A1, a flow sensor device containing a flow network is described. An apparatus for measuring the flow of current and the associated use of said apparatus are disclosed. The purpose of this invention is to realize an accelerometer that eliminates measurement errors caused by assembly errors or impurities in the air flow passing through it. Another purpose of this invention is to minimize measurement errors caused by measurements made from a single point. The product, which is realized in order to achieve the purpose of this invention and described in the first claim and the claims related to this claim, includes a flow sensor device. The flow sensor device includes a housing in the form of a pipe having a flow channel extending through it. The flow channel extends between an inlet and an outlet, and an axis passes through the center of the flow channel. Air enters the flow channel through the inlet and exits through the outlet. The flow channel includes a protrusion in the form of a ring extending along the wall of the flow channel to form a mouth. Thanks to the mouth, turbulence and vortices caused by the air flow passing through the flow channel are minimized. A flow sensor unit located near the mouth measures the air passing through. Thanks to the mouth, the airflow is aligned with the axis, turbulences and vortices are minimized, and an accurate measurement is made by placing the flow sensor unit near the mouth. In one embodiment of the invention, the flow channel includes at least two holes located near the mouth. The holes are preferably positioned symmetrically with respect to the axis. The holes are connected to each other through an airtight channel outside the holes. As the air passes through the mouth, some of the air enters the canal through the holes. The flow sensor unit measures the amount of air entering the duct. The number of holes can be increased to increase measurement accuracy. Air enters the channel through multiple holes, thus eliminating measurement differences caused by vortices and turbulence. Thanks to the holes and the channel connecting the holes, the flow sensor unit accurately measures the amount of air passing through the flow channel. In one embodiment of the invention, the channel extends all around the housing. By extending the channel all around the outside of the housing and thus the flow channel, a higher air flow can be achieved, thus eliminating measurement differences caused by vortices and turbulence inside the flow channel. In another embodiment of the invention, the channel extends all around inside the housing. In one embodiment of the invention, the holes are located adjacent to the mouth. In one embodiment of the invention, the holes are located in a position opposite the flow direction relative to the mouth. In another embodiment of the invention, the holes are located in a flow direction relative to the mouth. In one embodiment of the invention, the flow sensor is a pressure sensor. Pressure sensors offer an economical solution to the problem and can work with different types of air flows. In another embodiment of the invention, the flow sensor is a temperature sensor. The temperature sensor can accurately measure the amount of air flow passing through the flow channel. In one embodiment of the invention, the flow sensor device is used in a breathing support apparatus. Breathing aids require high precision and accuracy. Thanks to this invention, the mouth, holes and the channel connecting these holes enable accurate measurement. Measurement errors caused by eddies and turbulence are eliminated, and the amount of air passing through the flow channel is measured accurately. The drawings do not limit the scope of protection defined in the claims and should not be used alone to interpret the scope defined in the claims without referring to the technical explanation in the description part of this invention. Figure 1 7 is a perspective view of the breathing support apparatus. Figure 2 is the perspective view of the 7 flow sensor devices. Figure 3 7 is the perspective view of the flow sensor device along the A-A line in Figure 4. Figure 4 - is the top view of the flow sensor device without the flow sensor unit. Figure 5 - is a cross-sectional view of the flow sensor device. Figure 6 - is the cross-sectional view of the flow sensor device along the B-B line in Figure 4. The parts in the figures are numbered one by one, and the corresponding numbers are given below: 1. Flow sensor device 2. Slot 3. Input 4. Output. Flow channel 6. Flow sensor unit 7. Orifice 8. Orifice 9. Channel. Breathing support apparatus The flow sensor device (1) of the invention consists of a slot (2) and an air duct having an inlet (3), an outlet (4) and a flow channel (5) through which air flows following a central axis (I). (5) contains a flow sensor unit (6) that measures the amount of passing air. The housing (2) of the flow sensor device (1) contains the inlet (3) through which the air to be measured enters the housing (2) and the outlet (4) through which the measured air exits the housing (2). The flow channel (5) is in the form of a cylindrical pipe whose central axis (l) passes through the center of the flow channel (5). Air is measured through the flow sensor unit (6). The flow sensor device (1) of the invention also includes the flow channel (5), which is in the form of a ring extending along the wall of the flow channel (5) and contains a protrusion that forms a mouth (7) whose diameter is smaller than the diameter of the flow channel (5), and the axis ( I) passes through the center of the mouth (7) and the flow sensor unit (6) measures the air near the mouth (7). The flow channel (5) contains the mouth (7), which is a protrusion that narrows the flow channel (5) by protruding from the flow channel (5) towards the axis (I). Thanks to the nozzle (7), the air flow is aligned with the axis (I) and measurement differences caused by eddies and turbulence in the flow channel (5) are eliminated. In a preferred embodiment of the invention, the flow channel (5) contains at least two holes (8) near the mouth (7), and the holes (8) are formed by a channel (9) that is airtight and concentric with the axis (I), except for the holes (8). and the flow sensor unit (6) measures the amount of air passing through the flow channel (5) through the air entering the channel (9). The holes (8) are located adjacent to or close to the mouth (7) and the air passing through the flow channel (5) passes through them. The holes (8) are connected to each other via the channel (9). The channel (9) is airtight except for the holes (8). Air enters the duct (9) and the air amount is measured by the flow sensor unit (6). The position of the holes (8) is symmetrical with respect to the axis (I). The number of holes (8) can be increased to increase the accuracy of the measurements made by the flow sensor unit (6). By allowing air to enter the channel (9) through multiple holes (8), fluctuations caused by turbulence are eliminated. In a preferred embodiment of the invention, the channel (9) extends all around the slot (2). As a result, a wider flow channel (5) is obtained. In a preferred embodiment of the invention, the channel (9) extends all around inside the housing (2). In a preferred embodiment of the invention, the holes (8) are located in a position opposite the flow direction relative to the mouth (7). In another preferred embodiment of the invention, the holes (8) are located in a flow direction relative to the mouth (7). In a preferred embodiment of the invention, the flow sensor unit (6) is a pressure sensor and/or a temperature sensor. In a preferred embodiment of the invention, the flow sensor device (1) is used in a breathing support apparatus (10). An advantage provided by the invention is that the air passing through the flow channel (5) can be measured accurately by eliminating fluctuations. As a result, the flow sensor unit (6) can accurately measure the amount of air passing through it. TR TR

Claims (1)

1.CLAIMS. A housing (2) having an inlet (3), an outlet (4) and a flow channel (5) through which air flows following a central axis (l), and a flow sensor unit (which measures the amount of air passing through the air channel (5) 6) the flow channel (5), which is in the form of a ring extending along the wall of the flow channel (5) and contains a protrusion that forms a mouth (7) whose diameter is smaller than the diameter of the flow channel (5), where the axis (l) passes through the center of the mouth (7), and a flow sensor device (1) characterized by a flow sensor unit (6) that measures the air near the mouth (7). . The flow channel (5) containing at least two holes (8) near the mouth (7) and the holes (8) and the channel (9) connected to each other through a channel (9) that is airtight and concentric with the axis (I) outside the holes (8). ) A flow sensor device (1) as in Claim 1, characterized by a flow sensor unit (6) that measures the amount of air passing through the flow channel (5) through the incoming air. A flow sensor device (1) as in any of the above claims, characterized by the channel (9) extending all around the housing (2). . A flow sensor device (1) as in Claims 1 to 2, characterized by a channel (9) extending all around inside the housing (2). . A flow sensor device (1) as in Claims 2 to 4, characterized by holes (8) located in a position opposite the flow direction relative to the mouth (7). . A flow sensor device (1) as in Claims 2 to 4, characterized by holes (8) located in a position in the flow direction relative to the mouth (7). . A flow sensor device (1) as in any of the above claims, characterized by the flow sensor unit (6) which is a pressure sensor and/or a temperature sensor. . A flow sensor device (1) as in any of the above claims, wherein the flow sensor device (1) is used in a breathing support apparatus (10). TR TR