CZ309111B6 - A device for measuring the speed of air flow from the gap of the lip organ pipe - Google Patents

Abstract

The device for measuring the air flow rate from the lip of a lip organ pipe, comprises the body (1) of the device, in which the electronic board and the differential pressure sensor are arranged and on which the control buttons (6) are located and a display (2); and a replaceable probe (3), corresponding to the dimensions of the measured pipe, consisting of a rigid thin-walled tube for inserting the measured organ pipe into the foot of the measured pipe, the end (4) of the tube is cut obliquely at an angle of 45 and sealed tightly with a seal at the same inclination, the longest dimension of the cut tube is the lower part of the tube, and at the end (4) at the bottom of the tube there is an inlet measuring hole (5) and the other end of the tube is inserted into the body (1) of the device, by an airtight connection by a flexible hose to a differential pressure sensor connected to the electronic board of the jig.The method of measuring with the jig involves switching on the jig with the inserted probe (3) and inserting the closed end (4) of the probe (3) with the measuring hole (5) parallel to the plane of the upper surface of the core into the tube of the organ pipe above the gap so that the measuring hole (5) of the probe (3) is as close as possible to the centre of the gap and as low as possible above the gap, the lower part of the tube touches the upper edge of the lower lip of the whistle, and faces the flow of air coming out of the gap, after insertion, the probe (3) gradually moves in the measured area above the gap, the measured values are continuously electronically evaluated, the instantaneous and maximum value of the air flow rate are shown on the display (2).

Description

A device for measuring the air flow rate from a lip organ tube

Field of technology

The invention relates to a device with a probe for measuring the air flow rate from a retinal organ tube gap. This velocity, the magnitude of which affects the wording of the whistle and the method of its intonation, allows the probe to measure all known types of lip organ pipes and is part of a device for measuring the air flow rate from the lip of the lip organ pipe. The device with a probe can be used for measurements in the organ in situ even without disassembling the whistle. The sensor in the electronic part of the device, to which the probe is airtightly connected, measures the differential pressure change in the probe, which is proportional to the air flow rate around the probe measuring hole, and the calibrated speed value is then shown on the display. Storing the data and displaying it on the backlit display allows the probe to be measured even in adverse lighting conditions, and even in cases where the whistle is difficult to access and the instrument display is not visible at the time of measurement.

State of the art

The speed of air flow from the gap is one of the factors determining the sound of the organ pipe (see eg Otčenášek, Z., et al .: Retná organ pipe and its basic intonation setting, ISBN 97880-7331-467-5, AMU, Prague 2018). The gap is delimited by the space between the lower lip of the labia (with the overlay of wooden whistles) and the core. Structurally, it has many forms, but its purpose is always to speed up and equalize the air flow, which is when the air valve is opened by the air pressure on the air chamber pushed through the foot of the whistle into the space of the foot. The gap has a length corresponding to the width of the paw and the width given by the distance of the lower lip / overlap from the front of the core. The profile of the width of the gap from foot to foot can vary, but for the intonation setting and for the recognition and wording of the sound, the speed with which the air particles emerge from such a narrow gap and subsequently continue to flow in the space of the foot determines.

No type of operating meter has been available to measure the velocity of the air flow from the gap. In the laboratory, it can be measured using special instruments based on cooling the heated attachment or laser particle tracking technique (PIV). These methods are unsuitable for measurement in organ practice. For this purpose, a solution is proposed in the form of inserting a reasonably small probe into the space just above the gap, which does not yet significantly affect the flow rate, and connecting this probe to an electronic speed sensor based on pressure change in the probe caused by air flow around the measuring hole at the end of the probe. . This method of measuring the flow velocity from the gap then allows a sufficient degree of objectification of intonation procedures in organ practice (intonation sound-forming factors see eg Koukal, P .: Organs of the Brno and Loket schools and their sound ideals, ISBN 978-80- 907357-2- 9, National Monuments Institute 2019).

The pipes in the organ are usually inserted between other pipes and are located on several floors of the air ducts, so they are difficult to access. It is usually dark in the cramped space of the organ, so it is not easy to see on the measurement or on the scale without additional lighting. The presented solution of an electronic device with a probe for measuring the air flow rate from the groove of the retro organ pipe allows both operational measurement of this sound-forming parameter and in situ measurements under difficult light and space conditions. A set of probes is suitable for adapting to the specific dimensions of the whistle, but a basic probe with a diameter of 2 to 2.5 mm and a length of 100 mm is sufficient to measure the speed of the most common lip whistles.

Due to its shape and dimensions, the probe minimizes the influence of the flow and ensures the stability of the measured speed values. In organ practice, the device with a probe makes it possible to measure this physical parameter, which fundamentally affects the sound of the organ organ and its recognition.

- 1 CZ 309111 B6 and it has not yet been possible to quantify it by conventional means. The present invention thus provides a means of measuring the velocity profile of the flow from the whistle and, if necessary, ensuring its uniformity, and how to compare and balance the velocities of the flow through the whistles of adjacent register tones, which reduces noise in the sound of whistles and objectifies, speeds up and improves the process of intonation of organ registers.

The essence of the invention

The present invention relates to a device for measuring the air flow rate from a retinal organ tube gap comprising a replaceable probe corresponding to the dimensions of the measured pipe and a method of measurement.

The probe consists of a rigid thin-walled tube, which is so small in diameter that it can be inserted over the gap into the organ tube. The end of the tube is cut obliquely at an angle of 45 ° and sealed at the same inclination with a solid cap, the longest dimension of the cut tube is the lower part of the tube. The inlet measuring hole is located at the bottom of the tube at the very end at its closure and its size (up to the dimension of the inner cross-section of the tube) is determined by the properties of the electronic flow sensor. Adherence to the inclination of the end and the location of the measuring hole are necessary to ensure a wide range of speeds, which in practice occur with conventional lip whistles in the range of air pressures used on the air tube. The length of the probe tube must be greater than the depth of the lower lip of the labia (or, in the case of a wooden whistle, its blanket) of the measured organ pipes (usually up to 100 mm). At the other end of the tube, the probe is inserted into the body of the device, in which it is airtightly connected by a flexible hose to a differential pressure sensor connected to the electronic plate of the device. There are also control buttons and a backlit display on the body of the device.

To measure the flow of both very small and very large whistles, it is necessary to use several exchangeable probes with graduated diameter and length (eg diameter 1, 2, 3, length 50, 100, 150 mm), which then have their own calibration of speed values. and their dimensions cover a range of all common whistle sizes. The conversion of the pressure values from the differential pressure sensor to the speed shown on the display is calibrated separately for each of the probe dimensions. When replacing a probe, the calibration corresponding to the probe must be selected with the control button.

The method of measuring the air flow rate from the retinal organ tube gap involves switching on the jig with the inserted probe corresponding to the dimensions of the measured tube, by long pressing the control button. The calibration button corresponding to the given probe is selected with the control button. The end of the probe with the measuring hole is inserted parallel to the plane of the upper surface of the core into the tube of the organ above the gap so that the measuring hole of the probe is as close as possible to the center of the gap and as low as possible above the tube. to face the flow of air coming out of the gap. After insertion, the probe gradually moves in the range of the measured area above the gap, while moving slightly in all directions. The measured values are continuously evaluated electronically, while the instantaneous and maximum value of the air flow rate are shown on the display. After reading the maximum measured value, the display can be reset using the control button to prepare the instrument for further measurements. The product is switched off by long pressing the control button.

Explanation of the drawing

Giant. 1 shows an embodiment of a device for measuring the air flow rate from a retinal organ tube gap.

Example of an embodiment of the invention

An example of an embodiment of a device for measuring the air flow rate from a retinal organ gap

- 2 CZ 309111 B6 pipes with a probe is shown in Fig. 1. The device consists of a body 1 in which there is an electronic board with a display 2, which is backlit during the measurement. The electronic board contains a differential pressure sensor which, after calibration to the dimensions of the selected probe 3, electronically senses the air flow rates from the lip organ tube and is connected in the body 1 of the device by a tube to the probe 3, 5 of which is sealed at an angle of 45 °. There is an inlet measuring hole 5 at the bottom. On the body 1 of the jig there are buttons 6, which can be used to switch the jig on, off, select the probe calibration and reset the display 2.

The method of measuring the air flow rate from the retinal organ tube comprises switching on the device with the inserted probe 3 corresponding to the dimensions of the measured pipe, by long pressing the control button 6. The control button 6 further selects the calibration corresponding to the probe 3. Closed end 4 of the probe 3 with measuring hole 5 is inserted parallel to the plane of the upper surface of the core into the organ tube above the gap so that the measuring hole 5 of the probe 3 is as close as possible to the center of the gap and as low as possible above the gap when the lower part of the tube touches the upper edge the air flow coming out of the gap. After insertion, the probe 3 gradually moves in the range of the measured area above the line, while moving slightly in all directions. The measured values are continuously evaluated electronically, while the instantaneous and maximum value of the air flow rate are shown on display 2.

Claims (2)

PATENT CLAIMS A device for measuring the air flow rate from a retinal organ tube, characterized in that it comprises a device body (1) in which an electronic board and a differential pressure sensor are arranged and on which are control buttons (6) and a display (2). ; and a replaceable probe (3) corresponding to the dimensions of the measured organ pipe, which consists of a rigid thin-walled tube for insertion above the gap into the tube of the measured organ pipe, where the end (4) of the tube is cut obliquely at 45 ° and sealed with a tight seal , wherein the longest dimension of the cut tube is the lower part of the tube, and wherein at the end (4) at the bottom of the tube there is an inlet measuring hole (5) and at the other end of the tube the probe (3) is inserted into the body (1). is airtightly connected by a flexible hose to a differential pressure sensor connected to the electronic board of the jig. A method of measuring the air flow rate from a lip organ tube by means of a jig according to claim 1, characterized in that it comprises switching on the jig with an inserted probe (3) corresponding to the dimensions of the measured whistle by long pressing the control button (6), selecting a calibration corresponding to said probe ( 3) a control button (6), and further insert the closed end (4) of the probe (3) with the measuring hole (5) parallel to the plane of the upper surface of the core into the organ pipe above the gap so that the measuring hole (5) of the probe (3) was as close as possible to the center of the gap and as low as possible above the gap, when the lower part of the tube touches the upper edge of the lower lip of the whistle, and to face the air flow coming out of the gap and while moving slightly in all directions, the measured values are continuously evaluated electronically, while the instantaneous and maximum value of the air flow rate are shown on the display (2).