NO322838B1 - Vibration damper for ultrasonic bulbs and painter with such damper - Google Patents

Abstract

According to a first aspect, the invention comprises a vibration damper for ultrasonic waves in a gas stream and which comprises at least one damper element (3) which can be inserted for the gas flow in a line. 1 according to the invention, the vibration damper for ultrasonic waves is characterized in that at least one scattering unit (5, 6, 7) which has several reflection surfaces with a small surface is arranged in the damping element (3).

Description

The present invention relates to an oscillation damper for ultrasonic waves in a gas flow and which comprises at least one damping element which can be inserted into a line for the gas flow.

From the state of the art, vibration dampers for sound waves in the acoustic range (20 Hz - 20kHz) have long been mainly known. These are e.g. inserted into the exhaust stream of motor vehicles to reduce as much as possible the emission of sound waves in the acoustic area or to avoid it altogether.

In the efforts to reduce as much as possible the emission of sound waves in the acoustic area also at industrial plants, in order to thereby fulfill environmental protection obligations, throttle valves for controlling gas flows have been known in recent times, which instead of emitting sound waves in the environmentally relevant, acoustic range and which are due to the throat process, rather produce sound waves in the environmentally uncritical ultrasound range (> 20 kHz), especially between 2 kHz and 63 kHz.

Such emission of ultrasonic waves by means of modern throttle or throttle valves leads on the one hand to the fulfillment of environmental obligations, but on the other hand to conflicts with flow rate measuring devices which are often inserted in regulation circuits for setting a gas flow rate, and which work according to the ultrasound principle. The ultrasonic waves produced by modern throttle valves lead to quite considerable functional disturbances in known flow rate measuring devices that work according to the ultrasonic principle, or to their failure altogether.

The invention therefore has the task of providing an oscillation damper in the ultrasonic range, particularly in connection with flow rate measuring devices, and which works according to the ultrasonic principle.

The invention thus relates to an oscillation damper for ultrasonic waves in a gas flow, which comprises at least one damping element for the gas flow in a line, and which has as a distinctive feature that the damping element is arranged in at least one spreading unit which exhibits a number of reflection surfaces with small surface.

With an embodiment according to the invention, it is ensured that the ultrasound waves are reflected very frequently so that there is a high probability that there is destructive interference - and thereby annihilation - of ultrasound waves along the extended acoustic paths, which leads to a strong attenuation of the ultrasound waves' amplitude.

If the dimensions of the reflection surfaces lie roughly in the range of the wavelengths of the ultrasound waves, it is also ensured that the greatest possible number of the reflection surfaces which are effective against the ultrasound waves, are accommodated within a predetermined volume. Reflection surfaces with dimensions in the area below the wavelengths of the ultrasound waves are not "visible" or only conditionally "visible" to the ultrasound waves, while reflection surfaces in the area above the wavelengths of the ultrasound waves are indeed "visible" to the ultrasound waves and thereby lead to a reflection, but at the same time take up an unnecessary amount of space .

The probability of destructive interference in connection with the longest possible acoustic paths then becomes particularly large when the reflection surfaces are irregularly aligned.

A further improvement of the damping for the vibration damper according to the invention against ultrasonic waves is then ensured by the fact that the reflection surfaces of the spreading unit are at least partially curved. Such a curvature of the reflection surfaces leads to the formation of vortices inside the gas flow, which likewise leads to attenuation of the ultrasound waves' amplitude.

Is at least a canvas layer or a layer of a similar textile material arranged on and/or

in the damping element, a further reduction in the amplitude of the ultrasound waves is ensured due to the amount of disturbances in the gas flow through the canvas.

One particularly advantageous embodiment of the vibration damper for ultrasonic waves according to the invention is achieved in that the damping element, as with known conventional damping elements for sound waves in the acoustic area, consists of a hollow, tubular body which is closed at one end. Such a damping element is simple and inexpensive to produce and can also, for example, take over from silencers for sound waves in the acoustic range, as mentioned.

Experimentally, a diameter of approximately 20 mm of the openings in the damping element has been shown to be particularly advantageous with regard to the vibration damper's damping properties.

With a damping element consisting of a hollow, tubular body which is closed at one end, it has proven particularly advantageous to arrange at least one spreading unit on the inside of the damping element, which exhibits an open geometric structure directed inwards from the outside. The open geometric structures can have quite different cross-sections. They can e.g. have a circular, square or similar shape.

A further advantageous embodiment of the vibration damper according to the present invention is achieved by the damping element being filled with several spreading units. With this measure, it is ensured that the reflection surfaces are largely irregularly aligned without the spreading units having to have an unnecessarily complicated structure.

In the event that the damping element is filled with a number of spreading units, so-called pallet rings constitute particularly advantageous spreading units. Such pallet rings on the one hand exhibit a number of small reflection surfaces, while on the other hand the reflection surfaces are arranged in such a way that a vortex is very likely to be obtained which causes further attenuation of the ultrasound waves' amplitude.

As with silencers for sound waves in the acoustic range, it is also particularly advantageous with respect to the silencer according to the present invention that the damping element is made with adaptation to a curved line. The further extended acoustic path achieved by means of this curvature leads to further attenuation of the amplitude of the ultrasound waves.

According to another aspect, the invention relates to a flow rate meter that works according to the ultrasonic principle. Such a flow rate meter is known from e.g. DE 195 30 807.

According to the invention, in an apparatus for measuring flow rate and which works according to the ultrasound principle, an oscillation damper for ultrasound waves is arranged as stated above, between an ultrasound source and the flow rate meter. With this measure, it is advantageously ensured that the flow rate meter, which works according to the ultrasound principle, cannot be affected by ultrasound waves from foreign sources with regard to its function.

In detail, there are now many possibilities for the design and further development of an oscillation damper for ultrasonic waves according to the invention for use in a gas flow. In this context, reference is made to, on the one hand, patent claims 2-11, which are subordinate to patent claim 1, and, on the other hand, the following description of preferred embodiments seen in connection with the attached drawings, in which: Fig. 1 is a principle sketch of a flow rate meter that works according to the ultrasonic principle,

fig. 2 shows an exemplary embodiment of a damping element according to the invention, fig. 3a) and 3b) show a section through a first and second embodiment, respectively

on a spreading unit according to the invention,

fig. 4a) and 4b) show a third embodiment of a spreading unit according to

the invention, seen from two different directions,

fig. 5 shows the output signal from a flow rate meter that works according to the ultrasonic principle, without an oscillation damper according to the invention being arranged

between an ultrasound source and the flow rate meter, and

fig. 6 shows the output signal from a flow rate meter that works according to the ultrasound principle, and where an oscillation damper according to the invention is arranged between an ultrasound source and the flow rate meter.

In fig. 1 in the drawings shows a flow rate meter which works according to the ultrasound principle and which has two ultrasound transducers 1, 2 of which one always emits ultrasound waves which are received by the other. This happens alternately, i.e. that each of the ultrasound transducers 1, 2 serves alternately as transmitter and receiver. With such a system, gas flow is determined while speed based on the following formula:

where:

/ = the distance between the two ultrasound transducers 1, 2,

p = the angle for the propagation of the ultrasonic pulses in relation to the direction of the gas flow, peak = the propagation time upstream,

<t>down<=> the propagation time downstream.

With this assumed relationship, the following relationship applies to the error in the measurement signal for the flow rate:

where:

f = the frequency of the ultrasound signal from the ultrasound transducer 1, 2, and

S/N = signal/noise ratio of the measurement signal.

According to the invention, in order to reduce the amplitude of ultrasound waves in a gas flow and thereby achieve an improvement in the signal/noise ratio, a damping element is formed, e.g. in the form of a hollow, tubular body which is closed at one end. Such a damping element 3 is shown in fig. 2. The damping element 3 shown in fig. 2 is clamped with its connecting flange 4 between two connecting flanges in a pipeline (not shown).

On the inside of the damping element 3, there is e.g. arranged a spreading unit 5 which exhibits open geometric structures directed from the outside and inwards, as shown in the design example in fig. 3a), where a section through a section of this spreader unit 5 is shown. In the ideal case, the spreader unit 5 has a depth in the direction of flow that lies in the range of the wavelength of the ultrasound waves. An alternative second spreading unit 6 is in fig. 3b) also shown in section. These spreading units 5, 6 can, on the one hand, be arranged on the inside of the damping element 3 as a spreading unit with an overall cylindrical shape, and on the other hand irregularly fill the damping element 3 in the form of several small spreading units with equal or similar cross-sections. Both options can also be used cumulatively. However, it is essential that the damping element 3 has the largest possible amount of reflection surfaces with a small surface by means of spreading units 5, 6 which are arranged therein.

So-called pallet rings 7, as shown in fig. 4, have proven to be particularly suitable as spreading units for irregular filling of the damping element 3. Such pallet rings 7 are essentially cylindrical and preferably have rectangular openings 8 in the cylinder casing. These are clearly seen in fig. 4a). On the inside, the pallet rings 7 also have paddle-shaped, curved guide elements 9 which produce the desired swirling movements in the gas flow, which dampens the amplitude of the ultrasound waves. These guide elements 9 are clearly seen in fig. 4b).

A further, not previously mentioned advantage of the vibration damper according to the invention lies in the fact that residual ultrasonic waves at the output of the vibration damper come out very dispersed so that they spread out in all directions. Thereby, a further reduction in the impact of ultrasound waves on e.g. a flow rate meter by an extended distance between the vibration damper and the flow rate meter or by means of ultrasonic transducers with strong direction-dependent reception characteristics.

In fig. 5 in the drawings shows a measurement signal 10 from a flow rate meter that works according to the ultrasonic principle, for the volume flow rate recorded on the right in m<3>/h as a function of time. In fig. 5, the opening 11 of a throttle valve is also shown as a function of time. It can be clearly seen that despite the still open throttle valve, the measurement signal 10 breaks down above a critical value due to a strongly increasing signal/noise ratio. This is of course undesirable.

In fig. 6 in the drawings finally shows a measurement signal 10 for a flow meter for volume flow rate, which works according to the ultrasound principle, and where in the gas flow between the throttle valve which serves as an ultrasound source and the flow rate meter, an oscillation damper for ultrasonic waves according to the invention is arranged. It can be clearly seen that the flow rate meter delivers an error-free measurement signal 10 up to high volume flow rates. In fig. 6 of the drawings also shows the pressure drop 12 drawn on the left above the oscillation damper for ultrasonic waves according to the invention. At a volume flow rate of approx. 2000 m<3>/h, this pressure drop amounts to 12 sec to approximately 0.5 bar.

Claims (12)

1. Oscillation damper for ultrasonic waves in a gas flow, which comprises at least one damping element (3) for the gas flow in a line, characterized in that at least one spreading unit (5, 6, 7) is arranged in the damping element (3) which exhibits a number of reflection surfaces with a small surface. 2. Oscillation damper as stated in claim 1, and where the dimensions of the reflection surfaces are roughly in the range of the wavelength of the ultrasound waves. 3. Oscillation damper as stated in claim 1 or 2, and where the reflection surfaces have an irregular alignment. 4. Oscillation damper as specified in one of claims 1 - 3, and where the reflection surfaces on the spreading unit (7) are at least partially curved. 5. Oscillation damper as specified in one of claims 1 - 4, and where at least a gas canvas layer is arranged on and/or in the damping element (3). 6. Oscillation damper as stated in one of claims 1 - 5, and where the damping element (3) consists of a hollow, tubular body which is closed at one end. 7. Oscillation damper as specified in claim 6, and where the holes in the damping element (3) have a diameter of approximately 20 mm. 8. Oscillation damper as stated in claim 6 or 7, and where at least one spreading unit (5, 6) which exhibits open geometric structures directed from the outside inwards is arranged on the inside of the damping element (3). 9. Oscillation damper as specified in one of claims 6 - 8, and where the damping element (3) is filled with several spreading units (5,6,7). 10. Oscillation damper as stated in claim 9, and where the spreading unit (7) has the form of pallet rings. 11. Oscillation damper as stated in one of claims 1 - 10, and where the damping element has a curved design to fit a curved wire. 12. Apparatus for measuring flow rate and which works according to the ultrasound principle, and where between an ultrasound source and the flow rate meter there is arranged an oscillation damper for ultrasound waves as stated in one of the patent claims 1-11.