FR2514128A1 - Pneumatic measuring bridge e.g. for gas temp. - has two branches each including enclosure imposing load loss as function of flow, and supply providing alternate flow - Google Patents

Abstract

The bridge contains two branches used to measure a parameter which affects the characteristics of a gas in one component of the bridge, e.g temperature, pressure, force. Each branch is formed by a chamber (12,14) which contains a gas and by a component (37,38) which improses a pressure-drop on the gas flowing in it. Pref. the pressure-drop varies as an approximately linear function of the flow-rate. A pneumatic supply (33) provides both branches in parallel, through the pressure-drop components (37,38). The supply (33) applies a periodic alternating flow to the bridge. A micro-flowmeter (43) measures the flow in a pipe which connects both branches. In one version, the bridge gives a signal which is a function of several parameters, including flow variation amplitude, supply pressure, pressure-drop and chamber state.

Description

Pneumatic measuring bridge
The present invention relates to the field of measurement by pneumatic means and it relates to a pneumatic bridge for measuring a parameter representative of the state of a bridge element influencing the characteristics of a gas in this element.

 The invention aims in particular to provide such a bridge making it possible to measure very diverse parameters, in particular the temperature difference between the gas occupying a working enclosure and the same gas occupying a reference enclosure, the pressure difference of the gas contained in a working enclosure and a reference enclosure, and the forces tending to deform a working enclosure containing the gas and therefore to modify the pressure of the gas in this enclosure.

 To this end, the invention provides a pneumatic measuring bridge which comprises two branches each constituted by an enclosure and by a member imposing on the gas passing through it a pressure drop, which advantageously varies according to a substantially linear function of the flow rate; a pneumatic supply supplying the two branches in parallel, from the pressure drop members; and imposing on the branches an alternating periodic flow; and a flowmeter for measuring the flow passing through a pipe connecting the speakers.

 The flow through the flow meter must be low enough not to significantly disturb the conditions prevailing in the enclosures. For this purpose, it is possible in particular to use a microdebitmeter of the type described in patent application FR No. 2 308 090 of the applicant organization, to which reference may be made. Such a microdebitmeter has the double advantage of being able to detect and measure very low flow rates and to provide an almost linear response.

A pneumatic bridge of the kind defined above makes it possible not only to carry out measurements relating to one of its constituent elements (measurements which may be absolute or differential), but also to provide an output signal representative of a function of several parameters . An analysis of the operation of the bridge indeed shows that the output signal s of the microdebitmeter can be represented by a function of the kind
s ~ Ap (adR / R + ss
In this formula, A denotes the amplitude of the variations.

flow rate, p pneumatic supply pressure,
R and bR the continuous and variable components of the pressure drop, C and dC a parameter representative of the state of the speakers and its variations, a and ss proportionality coefficients.

 It can be seen that the bridge thus constitutes a veritable calculating member making it possible to carry out an operation of adding the effects of two parameters concerning one of the speakers, the other of the pressure drop members.

It can also carry out a multiplication operation taking into account the effects of two parameters, one affecting the branches, the other feeding.

 In a particular application of the invention, the bridge is intended to measure the difference between the temperature of one of the chambers, which constitutes a reference chamber at constant temperature, and the other chamber designed so as to be in temperature equilibrium with the gas it contains. In this case, the reference enclosure and the pressure drop members are advantageously maintained at the same temperature, possibly by a common thermostatic circuit. In another application of the invention, the two enclosures are kept in the same state and the temperature differences between one of the pressure drop members, at constant temperature, and the other pressure drop member which plays the role of temperature sensor. In this case, the variations in the viscosity of the gas as a function of the temperature in the pressure drop member will make it possible to obtain an output signal.

The invention will be better understood on reading the following description of a particular embodiment of the invention and of a variant, given by way of nonlimiting examples. The description refers to the accompanying drawings, in which
- Figure 1 is a block diagram showing the essential components of a bridge according to the invention
- Figure 2 is a diagram showing the constitution of a pneumatic measurement bridge according to a first embodiment of the invention
- Figure 3 shows a fraction of a pneumatic bridge according to a second embodiment, belonging to a temperature measurement installation.

 In its basic principle shown in FIG. 1, the pneumatic measurement bridge comprises two branches, each of which comprises 1 in series, a pressure drop member 37 or 38 and an enclosure 14 or 12. In general, the two enclosures will be practically identical, in particular from the point of view of form and volume, as well as the pressure drop members provided so that the gas flow is laminar there.

 The two branches are supplied, in parallel and in an identical manner, by supply means 33 which pass, in the terminal parts of the branches, an alternating periodic flow rate, of approximately sinusodal shape. The supply means 33 have been shown provided with an inlet 32 making it possible to adjust the pressure p which prevails in the bridge.

 Between the enclosures 12 and 14, or between the lines 40 and 41 which connect them to the pressure drop members 38 and 37, is placed a communication line on which is interposed a microdebitmeter 43 which supplies an output signal s. This microdebitmeter is of a type traversed in operation by a sufficiently low flow rate so as not to significantly modify the pressure which prevails in the chambers 12 and 14.

 When, for example, the bridge is intended to follow the temperature variations imposed by the enclosure 12 on the gas which it contains, the assembly of the enclosure 14 and of the pressure drop members 37 and 38 can be maintained at constant temperature using the same thermostat 39. However, it is also possible to use two different thermostats, one to maintain the enclosure 14 at constant temperature, the other to maintain the pressure drop members 37 and 38 at the same temperature.

 The pneumatic bridge shown in FIG. 2, where the members corresponding to those of FIG. 1 have the same reference number, constitutes a particular embodiment intended for carrying out a differential measurement between the chambers 12 and 14, occupied by the same gas as we will assume to be air.

 The measurement bridge includes a gas supply to the chambers 12 and 14, at an alternating periodic flow rate. In the embodiment shown in Figure 2, this flow is created by pulsed thermal expansion. The means of thermal pulsation comprise a reservoir 33 which communicates with the bridge and in which is placed a heating resistor 34 associated with an electrical supply 35 supplying current slots. A fan -36 with permanent operation, placed in the reservoir 33 near the outlet thereof, maintains a permanent flow of air on the resistor 34 so as to cause alternating periodic pressure variations, which are in practice approximately sinusoEdales.

 The pneumatic bridge proper comprises two pressure drop elements 37 and 38 supplied in parallel by the reservoir 33 and respectively placed in series with the chambers 12 and 14.

 These pressure drop elements must be of dimensions such that the flow therein is capillary and therefore that the pressure drop is a substantially linear function of the average speed of the flow. For this purpose, the pressure drop elements can be formed by blocks pierced with several conduits in parallel, of a diameter such that the flow therein is laminar for the gas in question and the circulation speeds during operation.

 In the case illustrated in FIG. 2, where the pulsation means use a thermal source, the frequency of the oscillations can hardly be of an order of magnitude greater than the Hertz, due to the inertia of the resistor 34. In this case, the pressure drop elements can be made up of bars having a length of the order of a centimeter and pierced with a few holes of 0.2 mm in diameter.

 So that the pressure losses undergone by the gas passing through the elements 37 and 38 are well determined and constant, the temperature of these elements and of the gas passing through them must also be constant. For this purpose, the elements 37 and 38 are placed in an enclosure 39 occupied by a liquid whose temperature is kept constant, for example by a thermostatic circuit comprising a pump 18 and a thermostat 19.

 Such an arrangement makes it possible to obtain an average overpressure of the order of one third of the atmospheric pressure, with a pressure modulation whose amplitude is a few tens of mbar.

 The pressure drop elements 37 and 38 are advantageously as identical as possible. Likewise, it will generally be preferable to give speakers 12 and 14 the same volume. Under these conditions, the tubes 40 and 41 which connect the pressure drop elements to the speakers are at the same pressure when no imbalance occurs between the branches of the bridge.

 A microdebitmeter 43 is placed on a pipe 42 which connects the points of the two branches situated, in each branch, between the pressure drop element 40 or 41 and the enclosure 12 or 14. In the embodiment illustrated in the figure 2, this microdebitmeter is of the type described in patent FR 2 308 090. This microdebitmeter makes it possible to measure the flow rate which traverses the pipe 42, flow rate which can be sufficiently low not to appreciably modify the differential pressure between the two enclosures . The microdebitmeter comprises a sensor 44 in which is formed a chamber 45 interposed on the pipe 42. In this chamber is placed a heat-resistant element 46 of small thickness, which will generally be a wire, placed in an electrical measuring bridge 47.

The bridge 47 is supplied by a circuit 48 with electrical heating pulses. On the continuous flow in the pipe 42 and the chamber 45, an alternating flow is superimposed, at a frequency which is at least two orders of magnitude greater than the frequency of the pressure pulses supplied by the reservoir 33 to the elements 37 and 38. These pressure oscillations can be produced by a membrane 49, the constitution of which can be that of a loudspeaker membrane, excited by a coil at constant frequency. It is easy to give the coil a vibration frequency of the order of 2000 Hz, which is satisfactory from the point of view of the relationship with the frequency of the thermal pulses supplying the pneumatic bridge and the operation of the electrical part of the microdebitmeter 43 .

 The microdebitmeter 43, a full description of which can be found in patent FR 2 308 090, comprises, in addition to the bridge of '*' eatstcne 47 forming a separator and the power supply 48, a membrane excitation china and synchronous detection.

 The excitation and detection channel comprises an oscillator block 50, forming a time base, which provides a sinusoidal signal for excitation of the membrane on a first output and a square synchronization signal, having the same frequency and the same phase as the first, on a second exit. The imbalance signal of bridge 47, brought to a level sufficient to memorize it by an amplifier not shown, attacks two memory blocks 52 and 53. A phase shift block 51 supplies, in response to each slot of the square signal coming from the oscillator 50, two successive pulses which one control the memory 52, the other the memory 53. These pulses are emitted with a phase shift of half a period, to cause one to memorize the signal corresponding to a maximum scanning scanning speed the heat-resistant element, the other at a minimum speed. The two signals stored in 52 and 53 are applied to the inputs of a differential amplifier 54 provided with an analog output door (not shown) which is open when the two signals are available on the inputs of the amplifier.

 } Meatstone 47's bridge will generally be permanently supplied. It is of conventional constitution, the heat-resistant element 46 occupying a branch of a bridge. The power supply 48 drives one of the diagonals of the bridge while the other diagonal supplies the output signals. Such a device easily makes it possible to measure air flow rates at atmospheric pressure of the order of 0.1 mm3 / s.

 The pneumatic bridge which has just been described finds numerous applications. In particular, it can be used to measure the difference between the temperatures of the same gas occupying the two enclosures 12 and 14. In this case, the enclosures will advantageously have the same volume.

The theoretical analysis of the operation shows that, in this case, the pressure difference between the speakers is a substantially linear function of the temperature difference, as long as it remains small compared to the absolute temperature. The theoretical analysis, confirmed by experience, shows that we arrive, with speakers having a volume of the order of 40 cm3 at a sensitivity of the order of 100 mV / OC.

 The pneumatic bridge according to the invention can also be used to measure the pressure difference between the two chambers occupied by the same gas.

If one of the speakers has stable dimensions while the other is subjected to the action of a force which imposes volume variations proportional to the intensity of the force, an installation for measuring the high precision strength. In this case, it will be necessary to keep the two speakers at the same temperature.

 The invention is susceptible of numerous variant embodiments. FIG. 3 shows for example a pneumatic measurement bridge in which the pressure drop elements 37 and 38 are subjected to substantially sinusoidal pressure variations by a mechanical compression system comprising a cylinder 56 in which a chamber 57 is delimited by a movable or deformable wall 58. In the embodiment shown, this wall is constituted by a piston which a mechanism, not shown, displaces a sinusoidal alternating movement. The cylinder 56 and the pressure drop elements 37 and 38 are immersed in an enclosure 59 occupied by a fluid maintained at constant temperature by a thermostatic circuit 60. The bridge makes it possible to measure the temperature difference between the reference enclosure 12, maintained at constant temperature by a thermally insulated enclosure 61 occupied by a liquid which circulates in a thermostatic circuit 62 and the measurement enclosure 14.

 Many other alternative embodiments of the invention are obviously possible and it should be understood that the scope of the present patent extends to all of these variants which remain within the framework of equivalences.

Claims (6)

Claims  1. Pneumatic bridge for measuring a parameter influencing the characteristics of a gas in a bridge element, characterized in that it comprises two branches each constituted by an enclosure (12 or 14) and by a member (38 or 37) imposing on the gas passing through it a pressure drop, which advantageously varies according to a substantially linear function of the flow rate, a pneumatic supply (33) supplying the two branches in parallel, from the pressure drop members, and imposing on the branches an alternating periodic flow; and a flow meter (43) for measuring the flow passing through a pipe connecting the speakers.  2. Pneumatic bridge according to claim 1, characterized in that the pressure drop members and the enclosures are substantially identical in the two branches.  3. Pneumatic bridge according to claim 1 or 2, characterized in that the pressure drop members (38, 37) consist of bars pierced with several small diameter holes.  4. Pneumatic bridge according to claim 1, 2 or 3, intended to measure the difference between the temperature of one of the chambers, which constitutes a reference chamber at constant temperature, and the other chamber designed so as to be in equilibrium with temperature with the gas it contains, characterized in that the reference enclosure and the pressure drop members are kept at constant temperature.  5. Pneumatic bridge according to claim 1, 2 or 3, characterized in that the two enclosures are maintained in the same state and 13 temperature difference is measured between one of the pressure drop members, at constant temperature, and the other pressure drop device which acts as a temperature sensor.  6. Pneumatic bridge according to claim 1, 2 or 3, characterized in that the bridge is mounted so as to provide an output signal representative of a function of several parameters, at least two of which belong to the group constituted by the amplitude of the variations in the periodic flow, the pneumatic supply pressure, the continuous and variable components of the pressure drop imposed by said members (38 or 37), a value representative of the state of the enclosures and the variations in this value.