JP2008151667A - Distance measuring sensor and facility instrument equipped with the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a distance measuring sensor accurately measuring the distance to an object by stabilizing the levels of transmission signals and reception signals, and also to provide a facility instrument provided with the same. <P>SOLUTION: The distance measuring sensor 100 is provided with: a casing 20; a supporting part 11 mounted to a sensor mounting part 22; a seating 12; a PZT oscillator 13; a resonance plate 14 for emitting transmission signals to the object by resonating with oscillations of the PZT oscillator 13; and a cone part 15 for receiving and amplifying reflected signals. An acoustic passage 23 for transmitting and receiving transmission signals, and reception signals and a space volume part 26 separated from the acoustic passage 23 by the supporting part 11, are formed in the casing 20. A sealing member 30 is provided between the acoustic passage 23 and the space volume part 26 to reliably cut off the acoustic passage 23 and the space volume part 26 from each other. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a distance measuring sensor that measures a distance to an object in a non-contact manner by transmitting and receiving ultrasonic waves, and a facility device including the distance measuring sensor.

  Conventionally, a non-contact distance measuring sensor (ultrasonic sensor) using a piezoelectric element PZT (lead zirconate titanate) is known. Such a distance measuring sensor oscillates the PZT vibrator by applying a pulse signal to the PZT vibrator, emits a transmission signal into the air, receives a reflection signal (reception signal) from the object, By using the time difference between the transmission time and the reception time of the received signal, the distance to the object is measured. Such a distance measuring sensor is based on the use of primary resonance of a PZT vibrator and a resonant metal plate (aluminum, steel plate, etc.) that is fixed to the PZT vibrator and resonates.

  As such, the transmitting unit that radiates the signal generated by oscillating the PZT vibrator into the air and the receiving unit that receives the reflected signal reflected by the target object in the air are placed at the same position. There is a technology to sufficiently attenuate the signal wave from the transmitter until the reflected wave reaches the receiver by extending the distance from the transmitter to the reflecting surface (water surface) using a reflector. It has been proposed (see, for example, Patent Document 1). The resonance frequency of the PZT vibrator is about 40 kHz, and the frequency in the ultrasonic region is radiated (oscillated).

Japanese Patent Laid-Open No. 2001-59765 (6th page, FIG. 3)

  In the distance measuring sensor described above, there is no particular restriction on the mounting of the PZT vibrator to the housing (case). Therefore, there are cases where two volume spaces formed in the direction of a signal separated from the PZT vibrator and transmitted from the PZT vibrator communicate with each other. That is, it becomes one large volume space, and the pressure fluctuation in the space on the opposite side to the side where signals are transmitted and received with the PZT vibrator interposed therebetween affects all the volume spaces in the housing. When signals are transmitted and received under such circumstances, there is a problem in that the signal characteristics are adversely affected and the levels of the transmission signal and the reception signal are not stable. This problem also caused a quality defect.

  The present invention has been made in order to solve the above-described problems, and provides a distance measuring sensor capable of accurately measuring the distance to an object by stabilizing the level of a transmission signal and a reception signal, The equipment provided is provided.

  A distance measuring sensor according to the present invention includes a hollow housing, a support portion having a side surface attached to an inner wall surface of the housing, a pedestal attached to the support portion, a pedestal attached to the pedestal, and a piezoelectric element. A configured resonator, a resonance plate that is attached to the opposite side of the pedestal of the transducer and that emits a transmission signal that is a resonance wave toward an object by resonating with the vibration of the transducer, and the resonance A cone portion that is attached to a side opposite to the vibrator side of the plate and receives and amplifies a reflected signal reflected by the object, and the support unit causes the transmission signal and the An acoustic path for transmitting and receiving a reflected signal, and a space volume section blocked from the acoustic path are formed.

  In the distance measuring sensor according to the present invention, the acoustic passage formed in the housing and the space volume portion are blocked by the support portion so as not to communicate with each other, so that the pressure fluctuation in the space volume portion is propagated to the acoustic passage. You can avoid it. Therefore, in the acoustic path, the levels of the transmission signal (transmission signal) and the reflection signal (reception signal) are stabilized, and the distance to the object can be accurately measured. Moreover, since the equipment according to the present invention includes the distance measuring sensor having such an effect, it has the same effect.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is an explanatory diagram for explaining a distance measuring sensor 100 according to Embodiment 1 of the present invention. FIG. 2 is a longitudinal sectional view showing a sectional configuration of the housing 20. The configuration of the distance measuring sensor 100 will be described with reference to FIGS. 1A is a longitudinal sectional view showing a cross-sectional configuration of the distance measuring sensor 100, and FIG. 1B is a plan view showing a state of the distance measuring sensor 100 as viewed from above. In addition, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one.

  The distance measuring sensor 100 measures the distance to an object in a non-contact manner by transmitting and receiving ultrasonic waves. As shown in FIG. 1A, the distance measuring sensor 100 includes a sensor main body 10 and a housing 20 that houses the sensor main body 10. The sensor body 10 is configured by sequentially stacking a support 11, a pedestal 12, a PZT vibrator 13, a resonance plate 14, and a cone 15. The support portion 11 is attached to a sensor attachment portion 22 formed inside the housing 20 and supports the sensor main body portion 10. The pedestal 12 is attached to the support portion 11 and is for fixing the PZT vibrator 13.

  The PZT vibrator 13 is a piezoelectric element made of lead zirconate titanate, and is oscillated by applying a pulse voltage via the positive electrode terminal portion 17 and the negative electrode terminal portion 18. That is, the PZT vibrator 13 has a function of oscillating a sound wave (ultrasonic wave) in a predetermined frequency range (generally around 40 kHz) when a pulse voltage is applied. FIG. 1 shows an example in which the positive electrode terminal portion 17 and the negative electrode terminal portion 18 penetrate the support portion 11 and the pedestal 12 and are connected to the PZT vibrator 13. However, the present invention is not limited to this, and may be connected to the PZT vibrator 13 without penetrating the support portion 11 and the base 12.

  The resonance plate 14 is attached to the PZT vibrator 13 and has a function of generating a transmission signal by the oscillation of the PZT vibrator 13. This transmission signal has a shape having “nodes” corresponding to the central portion of the resonance plate 14 formed in a circular shape and “nodes” corresponding to the peripheral portion. The cone unit 15 has a function of receiving and amplifying a reflected signal from the object. The cone section 15 has a substantially isosceles trapezoidal shape, and the resonance plate 14 side forms a short side.

  The housing | casing 20 is hollow and is comprised by the cylindrical shape by opening an upper surface and a bottom face (FIG.1 (b)). And the sensor main-body part 10 is accommodated in the space formed in the inside of the housing | casing 20. FIG. That is, the sensor main body 10 is inserted into the housing 20 from the sensor insertion portion 25 that is an opening on the bottom surface side of the housing 20, and is supported by fitting the support portion 11 into the sensor mounting portion 22. It has become. The sensor insertion portion 25 is closed after the sensor main body portion 10 is inserted, and a space volume portion 26 is formed between the sensor insertion portion 25 and the sensor mounting portion 22. That is, the space volume portion 26 is formed by being cut off from the acoustic passage 22 by the support portion 11. If the sensor insertion part 25 is obstruct | occluded, the space volume part 26 will be sealed space and will have a fixed pressure.

  On the other hand, a space between the acoustic passage opening 21 and the sensor mounting portion 22, which is an opening diagram on the upper surface side of the housing 20, functions as the acoustic passage 23. The acoustic passage 23 is formed so as to be gradually reduced in diameter. Specifically, the thickness of the outer wall of the housing 20 is made substantially the same from the sensor mounting portion 22 toward the acoustic path opening 21 up to a predetermined distance, and gradually increases as the acoustic path opening 21 is approached. Configure to be thin. By doing in this way, the acoustic path 23 functions as a horn part. The acoustic passage 23 also functions as a passage for guiding the reflected signal reflected by the object to the cone portion 15.

  A sensor mounting portion 22 is formed at the end of the acoustic passage 23. The sensor mounting portion 22 is formed in a size that allows the support portion 11 to be mounted by providing a step on the outer wall of the housing 20. In the first embodiment, the acoustic passage 23 is gradually reduced in diameter so as to function as a horn portion. However, the present invention is not limited to this. For example, the housing 20 may be formed in a simple cylindrical shape. That is, the housing 20 only needs to be able to accommodate the sensor body 10 inside.

  Here, if the acoustic passage 23 and the spatial volume portion 26 communicate with each other, the pressure fluctuation in the spatial volume portion 26 will propagate to the acoustic passage 23, and a transmission signal transmitted from the resonance plate 14. The level of the (transmission signal) and the reception signal (reflection signal) received by the cone unit 15 will not be stable. The acoustic passage 23 and the space volume 26 have a constant volume, and since the pressure is determined by this volume, in order to stabilize the signal level of the transmission signal and the reception signal, they are reliably cut off from each other, It is required to be completely independent. That is, a constant air load is always applied to the resonance plate 14 and the cone portion 15, and a predetermined operation can be performed under this situation. When the fluctuation occurs, the resonance plate 14 and the cone portion 15 cannot execute a predetermined operation.

  When the pressure fluctuation from the space volume portion 26 propagates to the acoustic path 23, the displacement amount of the resonance plate 14 and the cone portion 15 is affected, and the influence also affects the electric charge (Q). Then, the fluctuation of the capacitance value becomes a mechanical fluctuation (compliance fluctuation), and consequently affects the sharpness (Q) indicating the acoustic characteristics when the resonance plate 14 and the cone portion 15 are vibrating. (See FIG. 3).

  Therefore, in the distance measuring sensor 100 according to the first embodiment, the support portion 11 blocks the space volume portion 26 and the acoustic passage 23 so that pressure fluctuations in the space volume portion 26 are not propagated to the acoustic passage 23. is there. Further, the distance measuring sensor 100 is provided with the sealing material 30 on the lower side of the support portion 11 so as to reliably block the acoustic passage 23 and the space volume portion 26 and to be completely independent from each other. The sealing material 30 is not particularly limited as long as it is a material that can block the acoustic passage 23 and the space volume portion 26 when the sensor main body 10 is mounted in the housing 20. For example, an adhesive such as an epoxy resin or silicon rubber may be used for the sealing material 30.

  In the first embodiment, the sealing material 30 is provided on the lower side of the support portion 11 and the acoustic passage 23 and the space volume portion 26 are blocked. However, the present invention is not limited to this. Absent. For example, the sensor body portion 10 may be mounted after the sealing material 30 is applied to the sensor mounting portion 22 before the sensor body portion 10 is inserted. In the first embodiment, the case where the sealing material 30 is provided on the entire lower surface of the support portion 11 is illustrated as an example. However, the seal material 30 is provided only at a position where the acoustic passage 23 and the space volume portion 26 communicate with each other. May be.

  If the acoustic passage 23 and the space volume portion 26 are blocked and completely independent, the air pressure from the acoustic passage opening 21 to the sensor mounting portion 22 in the acoustic passage 23 is always constant, and the resonance plate 14 has an air load. It can be in a state of being applied. When the resonance plate 14 vibrates, the air in the acoustic passage 23 is pushed out of the housing 20. Further, this air coincides with the dense wave of the sound wave generated by the resonance plate 14 and radiates concentrated air from the acoustic passage opening 21 all at once. That is, the influence of the pressure fluctuation of the space volume portion 26 can be kept from being constantly affected. Furthermore, if the length of the acoustic path 23 is configured to match the wavelength of the primary vibration mode wave, the resonance frequency of the acoustic path 23 can be matched, and a stable large acoustic level can be obtained from the acoustic path opening 21. The sound wave which has can be radiated.

  FIG. 3 is a graph showing acoustic characteristics when the resonance plate 14 and the cone portion 15 are vibrating. Based on FIG. 3, the acoustic characteristics when the resonance plate 14 and the cone portion 15 are vibrating will be described. In FIG. 3, the horizontal axis represents frequency (Hz) and the vertical axis represents sharpness (Q). The solid line A indicates the sharpness curve of the distance measuring sensor 100, and the wavy line B indicates the sharpness curve of the distance measuring sensor that does not block the acoustic path and the space volume portion.

  The sharpness (Q) indicates a tendency of acoustic characteristics representing the resonance state of the resonance plate 14 and the cone portion 15, and when a certain resonance phenomenon occurs, it has a tendency to have a steep peak. However, when the resonance plate 14 and the cone portion 15 are affected by some influence (effect of pressure fluctuation) and the resonance phenomenon is disturbed, the resonance plate 14 and the cone portion 15 tend to have a gradual peak. That is, the acoustic passage 23 and the spatial volume portion 26 are blocked from each other, and the completely independent distance measuring sensor 200 has the acoustic characteristics having a tendency as shown by the solid line A, but the acoustic passage and the spatial volume portion are blocked from each other. If the distance measuring sensor is not, the acoustic characteristics tend to be as shown by the broken line B.

  Therefore, in the acoustic characteristics having a tendency as shown by the wavy line B, the transmission signal cannot be transmitted from the resonance plate 14 with certainty, and the vibration of the cone portion 15 that receives the reception signal is inhibited, and the vibration at the time of reception does not work. The received signal will be deteriorated. That is, the signal levels of the transmission signal and the reception signal are not stable, which causes a quality defect of the distance measuring sensor. Therefore, in the distance measuring sensor 100, the sealing material 30 is provided in the sensor mounting portion 22 so that the resonance plate 14 and the cone portion 15 can always perform a stable operation, and the acoustic passage 23 and the space volume portion 26 are securely connected. It is cut off to make it completely independent.

  FIG. 4 is an explanatory diagram for explaining an outline of signal processing of the distance measuring sensor 100. Based on FIG. 4, the signal processing of the distance measuring sensor 100 will be described. First, a pulse voltage is periodically and repeatedly transmitted from the transmission circuit section (pulse oscillation section) 40 and applied to the PZT vibrator 13 via the positive electrode terminal section 17 and the negative electrode terminal section 18 (arrow A shown in FIG. 4). . Then, the PZT vibrator 13 oscillates a sound wave in a predetermined frequency range. The resonance plate 14 radiates a transmission signal (transmission signal) toward the object by the oscillation of the PZT vibrator 13.

  The reflection signal (reception signal) obtained by reflecting the oscillation signal from the object is received by the cone unit 15. This received signal is amplified by the cone unit 15 and input to the receiving circuit unit 41 (arrow B shown in FIG. 4). This receiving circuit unit 41 filters the received signal to remove noise, further amplifies it, and measures the peak value and the incident time. The value measured by the receiving circuit unit 41 is sent to the arithmetic processing circuit unit 42 (arrow C shown in FIG. 4). And the arithmetic processing circuit part 42 calculates the distance to a target object from transmission time and incident time. The arithmetic processing circuit unit 42 is configured to periodically transmit a pulse voltage to the transmission circuit unit 41 (arrow D shown in FIG. 4).

  FIG. 5 is an explanatory diagram for explaining the waveform of the oscillation signal (transmission waveform) and the waveform of the reflection signal (reception waveform). Based on FIG. 5, the transmission waveform and the reception waveform will be described with reference to FIG. In addition to the transmission waveform and the reception waveform (FIG. 5B) of the distance measuring sensor 100 according to the first embodiment, FIG. 5 shows the waveform of the pulse applied to the PZT transducer 13 (FIG. 5A). ) And a transmission waveform and a reception waveform (FIG. 5C) of the distance measuring sensor not provided with the sealing material 30. In FIG. 5, the horizontal axis represents time. FIG. 5 shows an example in which the residual vibration of the transmission signal and the reception signal is efficiently suppressed.

  When the pulse voltage S1 transmitted from the transmission circuit unit 40 is applied to the PZT vibrator 13, the PZT vibrator 13 oscillates, and the transmission signal S2 is radiated from the resonance plate 14 toward the object. At this time, since the acoustic passage 23 and the space volume portion 26 are in a state of being blocked from each other, pressure fluctuations in the space volume portion 26 do not propagate to the acoustic passage 23. Therefore, the level of the transmission signal S2 always has a stable waveform as shown in FIG. On the other hand, in a state where the acoustic passage 23 and the space volume portion 26 are not blocked from each other, the level of the transmission signal S2 'has an unstable waveform as shown in FIG. If the vibration of the resonance plate 14 is forcibly suppressed, the residual component is suppressed, and a more stable oscillation signal S2 can be created.

  The oscillating signal S2 is reflected by the object and becomes a reflected signal S3, which is received by the cone portion 15 after a lapse of T time. Also here, since the acoustic passage 23 and the space volume portion 26 are in a state of being cut off from each other, the vibration of the cone portion 15 is not hindered by the pressure fluctuation generated in the space volume portion 26, and the received reception signal is received. Amplification can be ensured. On the other hand, in a state where the acoustic passage 23 and the space volume portion 26 are not blocked from each other, the level of the reception signal S3 'has an unstable waveform as shown in FIG. If the vibration of the cone portion 15 is forcibly suppressed, the residual component is suppressed and a more stable received signal S3 can be created. Then, the arithmetic processing circuit unit 42 measures the distance to the object based on the time T required from when the oscillation signal S2 is radiated until the reflected signal S3 is received.

  As described above, the distance measuring sensor 100 provides the sealing material 30 to reliably block the acoustic passage 23 and the space volume portion 26 so that pressure fluctuations in the space volume portion 26 are not propagated to the acoustic passage 23. Yes. That is, the acoustic passage 23 and the space volume portion 26 are surely blocked by the sealing material 30 so that the resonance plate 14 and the cone portion 15 can always perform a predetermined operation under a constant pressure. Therefore, the levels of the transmission signal and the reception signal are stabilized, and the object can be measured more effectively.

Embodiment 2. FIG.
FIG. 6 is a schematic configuration diagram showing the overall configuration of the showcase 50 on which the distance measuring sensor 100 is mounted. A case where the distance measuring sensor 100 is applied to the showcase 50 will be described with reference to FIG. This showcase 50 is installed in a convenience store, a store such as a supermarket, and places food, beverages, and the like. As shown in FIG. 6, the showcase 50 includes a heat exchanger 51, a drain pipe 52 that collects drain water 55 generated from the heat exchanger 51 and flows down, and drain water that flows down from the drain pipe 52. And a drain tank 53 for storing 55.

  The distance measuring sensor 100 is attached above the opening on the upper surface of the drain tank 53. The distance measuring sensor 100 is arranged so that the acoustic passage opening 21 of the housing 20 faces the water surface in the drain tank 53. The wavy line indicates the ultrasonic wave (transmitted signal) transmitted from the distance measuring sensor 100 and the reflected wave (reflected signal) reflected on the water surface. That is, the distance measuring sensor 100 functions as a water level detection device for detecting the water level of the drain water 55 stored in the drain tank 53.

  In this case, the object is the water surface of the drain water 55 stored in the drain tank 53, and the distance from the distance measuring sensor 100 to the water surface, that is, the water level is detected. Since the distance measuring sensor 100 can efficiently measure the distance to the object, it can be used in such a form. In addition, although the case where one ranging sensor 100 is mounted on the showcase 50 has been described as an example, the present invention is not limited to this, and a plurality of ranging sensors 100 may be mounted.

  In the second embodiment, the case where the distance measuring sensor 100 is mounted on the showcase 50 has been described as an example. However, the present invention is not limited to this, and may be mounted in equipment such as an air conditioner. In other words, any equipment that aims to detect the distance to the object can be installed. For example, the distance sensor 100 is mounted on the main body or suction port of the vacuum cleaner to detect the distance to an obstacle in the room to be cleaned, or the distance sensor 100 is mounted on a bumper of an automobile to It is also possible to detect the distance to the guardrail.

  In each embodiment, the PZT vibrator 13 has been described as an example, but the present invention is not limited to this. For example, a piezoelectric element such as a ceramic piezoelectric element or a polymer piezoelectric element may be used. Moreover, although the case where the housing | casing 20 which concerns on Embodiment 1 was comprised by the cylindrical shape was demonstrated to the example, it is not limited to this. For example, the housing 20 may be configured in a prismatic shape, and the acoustic passage 33 may be hollowed out in a cylindrical shape. In this case, the support portion 11 may also have a shape corresponding to the shape of the sensor mounting portion 22 of the housing 20.

6 is an explanatory diagram for explaining a distance measuring sensor according to Embodiment 1. FIG. It is a longitudinal cross-sectional view which shows the cross-sectional structure of a housing | casing. It is a graph showing the acoustic characteristic when the resonant plate and the cone part are vibrating. It is explanatory drawing for demonstrating the outline | summary of the signal processing of a ranging sensor. It is explanatory drawing for demonstrating a transmission waveform and a reception waveform. It is a schematic block diagram which shows the whole structure of the showcase in which the ranging sensor is mounted.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 Sensor main-body part, 11 Support part, 12 base, 13 PZT vibrator | oscillator, 14 Resonance plate, 15 Cone part, 17 Positive electrode terminal part, 18 Negative electrode terminal part, 20 Case, 21 Acoustic path opening part, 22 Sensor mounting Part, 23 acoustic passage, 25 sensor insertion part, 26 space volume part, 30 sealing material, 40 transmission circuit part, 41 reception circuit part, 42 arithmetic processing circuit part, 50 showcase, 51 heat exchanger, 52 drain pipe, 53 Drain tank, 55 Drain water, 100 Ranging sensor.

Claims (8)

A hollow housing;
A support part having a side surface attached to the inner wall surface of the housing;
A pedestal attached to the support;
A vibrator attached to the pedestal and composed of a piezoelectric element;
A resonance plate that is attached to the opposite side of the pedestal of the vibrator and emits a transmission signal that is a resonance wave toward an object by resonating with vibration of the vibrator;
A cone portion that is attached to the opposite side of the resonator plate from the vibrator side, receives a reflected signal reflected by the object, and amplifies the cone portion;
By the support part,
An acoustic path for transmitting and receiving the transmission signal and the reflected signal, and a spatial volume section blocked from the acoustic path are formed in the casing. The distance measuring sensor according to claim 1, wherein a sealing material is provided between the acoustic path and the space volume portion. A sensor mounting part for attaching the support part to the inner wall surface of the housing is provided,
The distance measuring sensor according to claim 2, wherein the sealing material is provided on the sensor mounting portion. The distance measuring sensor according to any one of claims 1 to 3, wherein the acoustic passage is gradually reduced in diameter toward the cone portion. The distance measuring sensor according to claim 1, wherein the space volume portion is a sealed space. The distance measuring sensor according to claim 1, wherein the vibrator is configured by a piezoelectric element made of PZT. The distance measuring sensor according to claim 1, wherein the sealing material is an epoxy resin or silicon rubber. An equipment comprising the distance measuring sensor according to any one of claims 1 to 7.

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