FI80788B - FOERFARANDE OCH ANORDNING FOER ANGIVNING AV EN RIKTNING ELLER VINKEL. - Google Patents

Description

80788

METHOD AND APPARATUS FOR INDICATING DIRECTION OR ANGLE -FÖRFARANDE OCH ANORDNING FÖR ANGIVNING AV EN RIKTNING ELLER VINKEL

The present invention relates to a method and apparatus for detecting an angle or direction in which the position and direction of movement of a tilt-sensitive vial or similar balancing member are monitored by a light source-light detector system formed of photoelectric components.

U.S. Patent No. 3,863,067 and West German Application Publication No. 2,636,706 and the applicant's previous Finnish patent application no. 841864 discloses devices based on monitoring a gas bubble in a vial. In these publications, monitoring is performed by a single light source and a detector by observing the bubble interface using either X-ray or direct reflection. On the other hand, it is known from U.S. Pat. 4,182,046, from the English patent 1,528,445 and from the applicant's earlier Finnish patent application no. 870737 devices based on monitoring the movements of a gas bubble in a vial with two pairs of light source detectors.

Almost all known devices suffer from numerous disadvantages. One of these is that the gas bubble in the vial changes significantly in shape and size due to temperature. This fact causes considerable calibration and interpretation difficulties, especially in countries with large temperature fluctuations, such as Finland. In devices with two pairs of light source detectors, temperature fluctuations are problematic, especially due to the creep of the characteristics of the phototransistors. This could theoretically be remedied by matched pairs (photoelectrics are not on the market) or by compensation, but for practical applications these solutions are too cumbersome, expensive and uncertain.

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In addition, it has been found that the measurement result in known devices varies irregularly with different measurement times and only slides towards the correct value over a period of time. This is because a thin film of liquid, irregular and variable in thickness and uniformity, remains in the wall of the liquid tube of the vial above the bubble for at least some time. This is because there is constant drying and runoff in the film, which affects both the light passing through the film and the light reflected from it. Thus, the measurement results are vague whenever the position sensor observation light passes through the vial from top to bottom or during the day.

The object of the present invention is to obviate the above-mentioned drawbacks and to provide a method for detecting a direction and a suitable device capable of accurately detecting an angle and a direction of change regardless of the temperature and the formation of the above-mentioned film. To achieve this, the method according to the invention, in which the light beams reflected from the balancing element are detected and notified to the user by signaling devices when the electrical signals generated by the different light beams are in equilibrium, is characterized in that at least one light source is directed at the interface a substantially equal portion of the reflected light beams is caused to strike the surface of one or more detectors located at a substantially right angle symmetrically to the light sources.

Depending on the embodiment, the invention can achieve the following advantages over the prior art: - high accuracy, since the measured light beam in no case passes through the liquid film above the balancing element, 3 80788 - reliable direction detection, large lateral inclination allowed - no temperature change due to temperature changes affecting the Bubble or liquid does not interfere with the operation of the device.

A preferred embodiment of the method according to the invention is characterized in that the light beams produced by at least two light sources are directed to the interface between the liquid of the vial and the balancing member, and that the light beams reflected from the balancing member are collected on a single detector. With this embodiment, all the above-mentioned advantages are achieved with the simplest possible structure.

Another preferred embodiment of the method according to the invention is characterized in that a light beam produced by a single light source is directed at the interface between the liquid and the balancing member of the vial and that reflected light rays are collected on the surface of at least two detectors. Due to its multiple detectors, this embodiment is mainly suitable for applications where the temperature remains substantially constant.

Other preferred applications of the method according to the invention. . the shapes are characterized by what is set forth in the claims below.

The device according to the invention, which consists of one or more light sources such as light emitting diodes and one or more light detectors, such as phototransistors, mounted in connection with a tilt-sensitive vial known per se, and its control electronics with signaling devices for checking a certain angle or direction, at least one light source directed at the interface between the liquid and the balancing member of the vial and one or more detectors 4 80788 positioned symmetrically and at substantially right angles to the light sources so that the light rays reflected from the balancing member in the center position of the light sources are detectably substantially equal.

A preferred embodiment of the device according to the invention is characterized in that at least two light sources, such as LEDs, are directed at the interface between the liquid of the vial and the balancing element, and that the device comprises a single detector with which the light rays reflected from the balancing element can be detected.

Another preferred embodiment of the device according to the invention is characterized in that a single light source such as an LED is directed at the interface between the liquid of the vial and the balance member, and that the device comprises at least two detectors with which the light rays reflected from the balance member can be detected.

Other preferred embodiments of the device according to the invention are characterized by what is stated in the claims below.

The invention will now be described in more detail by means of examples and with reference to the accompanying drawings, in which

Figure 1 shows an example of an arrangement of a vial and a light source-receiver combination according to the invention, seen from the side of the vial,

Figure 2 shows the structure of Figure 1 as seen from the end of the vial,

Figure 3 shows a top view of the structure of Figure 1, 5 80788

Figure A shows another example of an arrangement according to the invention,

Figure 5 shows an example of an arrangement according to the invention using more than two light sources,

Fig. 6 shows a side view of the structure according to Fig. 5,

Figure 7 shows the electronics of a cowardly device of the invention with its signaling devices,

Fig. 8 shows the signal formats of the circuit of Fig. 7 in different situations,

Figure 9 shows the determination of the accuracy range of the device according to the invention.

In the following, the embodiments in which two or more light sources and one detector located below the leveling element of the vial are used are mainly considered. It is clear that the invention will not be eliminated and the operation of the device will not change for any reason if the light sources in the described two light source applications and the detector change location. On the other hand, if the light sources are replaced by detectors and the detector by a light source, an inverse application is obtained compared to the above, which is mainly suitable for constant temperature applications due to the different temperature sensitivities of the detectors. This reservation achieves all the other advantages mentioned above without departing from the basic idea of the invention.

Figure 1 shows an arrangement according to the invention for a vial, in which the vial itself is indicated by reference numeral 1, the liquid space contained in the vial and the liquid by number 2, and a liquid balancing element in the liquid 680. Two light sources 4a are mounted tightly against one side of the vial 1 and 4b, hereinafter referred to as light emitting diodes. The light emitting diodes are directed to the balancing member 3 of the vial 1 from the side parallel and substantially symmetrically with respect to the balancing axis A of the vial so that in the equilibrium position a substantial part of both light beams side the balancing member and are reflected downwards to the detector. The detector, which in this example consists of a phototransistor 5, is placed below the balance member 3, on the balance axis A of the vial. Here it is assumed that the axis A of the vial and the center of the balance member 3 coincide when the vial is horizontal. If this is not the case for some reason, the center of the balancing element will naturally become dominant and the light emitting diodes and detectors must be positioned accordingly. The attachment of the light emitting diodes and the phototransistor to the vial 1 is not shown here, but it can be done in a number of different ways, e.g. by screw connections or by gluing.

Figure 2 illustrates the direction of arrow B, leaving a light emitting diode light beam passage of the phototransistor 5, as Figure 3, which shows the two light-emitting diodes 4a and 4b and the corresponding passage of light represented by arrows B and C. The LEDs are positioned for the bubble with respect to 3, the bubble 3 curvature of the surface does not exactly give the light passes through the bubble to the other side of the vial, but most of the light is reflected from the surface of the bubble 3. It is noted that all the light emitted by the light emitting diodes 4a, 4b is by no means transmitted to the phototransistor 5, but is scattered elsewhere after reflection. It is not necessary to focus all the light on one point, but it is sufficient that the light emitting diodes and the phototransistor 5 form a symmetrical pattern with the bubble 3 in the center of the vial in its equilibrium position. Thus, the exact vertical height of the light emitting diodes and the exact position of the phototransistor in relation to the axis A in Fig. 2 are not very critical, because the pattern li 7 80788 formed by them remains symmetrical. Thus, the quality of the control electronics of the phototransistor 5 and its adjustments are the most crucial in terms of accuracy (see Fig. 7). In order to be able to distinguish the rays from the different light emitting diodes, it is usually necessary to pulse them alternately so that the phototransistor actually detects only the light rays coming from one diode at a time.

As is particularly clear from Figure 2, the direction of light travel in this exemplary embodiment may just as well be reversed as shown above. In this case, the light emitting diodes are located below the vial and the phototransistor on either side of it.

Figure 4 shows another embodiment of the invention in which the light emitting diodes 6a and 6b are arranged at the ends of the vial 1, the phototransistor 5 being in the same position as in Figures 1-3. Otherwise, the arrangement of Figure 4 corresponds exactly to the embodiment shown in connection with Figures 1-3.

Figures 5 and 6 show an example of the application of the invention to a multi-directional sensor using more than two light sources. Inside the cylindrical multidirectional label 7 there is also a cylindrical liquid space 8 in which a balancing member 9 is formed in the usual way. The label 7 is surrounded by eight similar and symmetrically arranged light emitting diodes 10a ... 10h. has been presented. By suitably connecting the pairs (e.g. 10c and 10g in Fig. 6) at a sufficiently fast rate to co-operate with the phototransistor 6, such a sensor provides unambiguous directional information about the inclination to e.g. an alarm or measuring device.

Fig. 7 shows an example of a circuit diagram by means of which the invention can be implemented, and Fig. 8 shows 880788 the main curve shapes present in the circuit according to Fig. 7 in different situations. Figure 8 is divided into three zones 1,11 and III, each of which represents the different positions of the balancing member of the vial to be observed, i.e. the bubble.

The operation of the circuit of Fig. 7 will now be reviewed with reference to Figs. 7 and 8. The circuit includes an oscillator 12 which supplies a resistive phase wave to the resistors R1-R4 at points D and E (see also Fig. 8). The frequency of the oscillator is of the order of 1 kHz, but nothing prevents it from being raised to 100 kHz, if necessary. When the state of point D is a logical one, the state of point E is zero, and the transistor T1 conducts, which in turn turns on the light emitting diode 13a, the intensity of the light emitted of which is adjustable by the trimmer RS. In this situation, the second light emitting diode 13b does not receive power and therefore does not light up. Correspondingly, the light emitting diode 13b is turned on by the transistor T2 and the light emitting diode 13a is turned off in the next cycle where E = 1 and D = 0. Thus, the light emitting diodes alternately emit light to the phototransistor 14. When the light emitted by one of the two light emitting diodes I3a, 13b hits the surface of the phototransistor 14, a current is generated therein which places the transistor T3 in a momentarily conductive state during which the RC circuits C1, R8 and C2, R9 are charged. Transistors T4 and T5 ensure that the current generated by the light emitting diode 13a charges the RC circuit. C1, R8 and the corresponding current of the light emitting diode 13b charge the RC circuit C2, R9.

The operational amplifier 15 is supplied with voltages generated at points F and G, which vary in the rate of charging and discharging of the RC circuits. If the bubble of the vial to be observed is now in equilibrium, the same amount of light has been reflected from the different directions (in this case two) to the phototransistor 14, whereby the RC circuits are equally charged. This: is shown in zone I of Fig. 8 as the average equal voltages of points G and F, where the intersection of the operational amplifier curves at positions 980788 connected comparatively to their inputs changes the state of its output, resulting in a square wave voltage according to H of Fig. 8. This signal is inverted at NAND gate 16 to obtain an inverse signal relative to H at point I. After rectification, the signals are applied to other RC circuits C3.R10 and C4, R11, the signal forms generated by which are represented by the curves of points J and K shown in Fig. 8. In the equilibrium zone I, the voltages of both point J and point K remain logical, so that the output of the AND gate 17 is also one, which in turn causes the light emitting diode L1 to illuminate via transistor T7.

If the leveling balance of the vial is not in its equilibrium position, i.e. if the situation is in zone II (tilt left) or zone III (tilt right) of Figure 8, then the voltages at points F and G are different at all times, so that the output of the comparator is logically zero or one. As will be readily appreciated by those skilled in the art, this results in the output of the AND gate 17 always being zero and, depending on the case, one of the control transistors T6 or T8 of the correction direction LEDs L2 and L3 causing the control diode to light to indicate the need and direction of the vial position correction.

The operational amplifier 18 monitors by means of the transistor T9, which acts as a current switch, that no directional information is given when receiving only very weak signals from the phototransistor 14, whereby the vial is in a very oblique position, e.g. 10 °. Otherwise, conflicting situations may arise, e.g. if the light emitting diodes 13a and 13b accidentally give signals of approximately the same size. If the device according to Fig. 7 is used, for example, in the embodiment according to Fig. 5, a simple logic must be connected to it, which goes through the different light-emitting diode pairs in turn in the same way as described above. Making such a connection is obvious to a person skilled in the art.

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The second embodiment of the invention having one light source and multiple light detectors is controlled in a manner similar to that described above, except that (if the electronics complexity is kept at the same low level as in Figure 7) that the light source is on continuously and the light detectors are controlled to receive reflected light rays each. in turn. It is within the skill of a person skilled in the art to be able to change the circuit solution according to Fig. 7 so that such an operation is achieved.

Figure 9 shows the voltage levels given by the phototransistor as a function of the position of the balancing element, i.e. the tilt angle α of the vial. The plane N represents the detection limit, here ± 10 ·, the curves O and P represent the output voltage of the phototransistor connected according to the invention at different vial angles a. It is observed that the reflections from the vial bubble to the light detector are not strongest when the vial is horizontal. The expression is based only on the detection of the intersection of the curves, and the accuracy inherent in the invention is due to the uniformity and symmetry of the curves O and P in all situations, which in turn is due to the fact that the curves O and P

; are produced by one and the same semiconductor component. The accuracy range R, the magnitude of which is primarily determined by adjusting the resistors R8 and R9 in Figure 7, is typically 0.005 °, which corresponds to the accuracy of the best known, but considerably more complex and expensive devices. The accuracy range can be adjusted, for example, by adding a transistor in parallel with each of the RC circuits C1, R8 and C2, R9 and adjusting their gain. Fig. 9 also shows the presence areas of the different guiding light emitting diodes L1-L3 of Fig. 7, by means of which the connection to Fig. 7 is easily indicated. The final fine-tuning of the shapes of the curves O and P can be performed with the adjustment resistors R5 and R6 in Fig. 7. As a result, the light emitting diodes do not have to be placed symmetrically with respect to the axis A of Fig. 1 with very high accuracy, because any strong differences in the detected reflection signal can easily compensate for the light intensity of the diodes by adjusting the above resistors. Equally, permanent differences in the intensity of the detected light due to a non-measurable object can be compensated.

It will be apparent to those skilled in the art that the various embodiments of the invention are not limited to the above examples, but may vary within the scope of the claims below. Thus, any device that produces signals sensed by the human senses, such as audible signals, can act as signaling devices. Different signaling devices can also be combined.

Claims (22)

A method for detecting an angle or direction, wherein the position and direction of movement of a tilt-sensitive vial <1; 7) or a corresponding balancing member (3; 9) is monitored by a light source-light detector system formed of photoelectric components, detecting light beams reflected from the balancing member (3; 9). informing the user by means of signaling devices (LI) when the electrical signals generated by the different light beams are in balance with each other, characterized in that at least one light source (4a, 4b; 6a, 6b; 10a) is directed at the interface between the liquid (1; 9) of the vial (1; 7) -10h) such that when the balancing member (3; 9) is in its central position, a substantially equal portion of the light rays reflected from the balancing member of the light source are hit at a substantially right angle to the surface of one or more detectors (5; 11) symmetrically with the light sources. Method according to Claim 1, characterized in that the light rays produced by at least two light sources (4a, 4b; 6a, 6b; 10a-10h) are directed at the interface between the liquid of the vial (1; 7) and the balancing element (3; 9), and that the light rays reflected from the balancing element are collected on the surface of a single detector (5; 11). Method according to Claim 2, characterized in that the two light beams produced by the light sources (4a, 4b) are directed laterally parallel to the balance element (3) of the vial (1) and substantially symmetrically with respect to the balance axis (A) of the vial so that a substantially equal portion of both light beams strikes the balance member (3) and is reflected downwardly therefrom to the detector (5) located below the vial. i3 80788 Method according to Claim 2, characterized in that the two light beams produced by the light sources are directed parallel to the balance element (3) of the vial (1) and substantially symmetrically with respect to the balance axis (A) of the vial so that in the equilibrium position a substantially equal part of both light beams to the balancing member (3) and is reflected laterally to the detector (5) on the side of the vial. Method according to Claim 2, characterized in that the two light beams produced by the light sources (6a, 6b) are directed to the interfaces between the liquid of the vial (1) and the balance member (3) from opposite directions at the ends of the vial. both light beams hit the balancing member (3) and are reflected downwards from it to the detector (5) located below the balancing member. Method according to claim 2, characterized in that the light rays produced by the more than two light sources (10a-10h) are directed laterally symmetrically in pairs in opposite directions to the balance member (9) of the circularly symmetrical vial (7) so that in the equilibrium position of both light beams of the light beam pair impinges on the balancing member (9) and is reflected downwards to the detector (11) located below the balancing member. Method according to claim 1, characterized in that a light beam produced by a single light source is directed at the interface between the liquid of the vial (1; 7) and the balancing member (3; 9), and that reflected light beams are collected on the surface of at least two detectors. i4 80788 Method according to Claim 7, characterized in that the light beam produced by one light source is directed laterally to the balance element (3) of the vial (1) so that in the equilibrium position a substantial part of the light beam hits the balance element (3) and is reflected downwards below the vial. (A) for two detectors arranged substantially symmetrically with respect to. Method according to claim 7, characterized in that the light beam produced by one light source is directed to the balance member (3) of the vial (1) from below so that in the equilibrium position a substantial part of the light beam hits the balance member (3) and is reflected laterally to its balance axis ( A) for two detectors arranged substantially symmetrically with respect to. Method according to claim 7, characterized in that the two light detectors are directed at the balance member (3) of the vial (1) in opposite directions from the ends of the vial so that at equilibrium a substantial part of the light beam produced below the balance member hits the balance member (3) and is reflected laterally on the surface of the detectors. Method according to claim 7, characterized in that more than two light detectors are directed laterally symmetrically in pairs in opposite directions to the balance member (9) of the circularly symmetrical vial (7) so that at equilibrium a substantial part of the light beam produced below the balance member hits the balance member ) and reflected from it sideways to each detector. Apparatus for carrying out the method according to claim 1, which apparatus consists of one or more light sources mounted per se in connection with a tilt-sensitive vial (1-7) ib 80788, such as light emitting diodes (4a, 4b; 6a, 6b, · 10a-10h) and one or more a light detector, such as phototransistors (S; 11) p and the electronics controlling them with their signaling devices (LI) for checking a certain angle or direction, characterized in that the device comprises at least one light source (4a, 4b; 6a, 6b; 10a-10h) directed at the vial; (1; 7) at the interface between the liquid and the balancing member (3; 9) and one or more detectors (5, 11) arranged symmetrically and at substantially right angles to the light sources so that the light sources (4a, 4b; 6a, 6b; 10a) -10h) the light rays reflected from the balance element (3; 9) in its central position can be detected substantially equally strongly. Device according to Claim 12, characterized in that at least two light sources, such as LEDs (4a, 4b; 6a, 6b; 10a-10h), are directed at the interface between the liquid of the vial (1; 7) and the balancing element (3; 9), and that the device comprises a single detector (5; 11) with which the light rays reflected from the balancing element can be detected. Device according to Claim 13, characterized in that two light sources, such as LEDs (4a, 4b), are directed laterally parallel and substantially symmetrically to the interface of the liquid and balance element (3) of the vial (1) with respect to the balance axis (A) of the vial. in the equilibrium position, the optical axes of both LEDs (4a, 4b) substantially impinge on the equilibrium member (3), and that the detector (5) is located below the vial (1). Device according to Claim 13, characterized in that two light sources, such as LEDs (4a, 4b), are directed at the interface between the liquid and the balancing element (3) of the vial (1) from below in parallel and substantially symmetrically with respect to the balance axis (A) of the vial. in the equilibrium position, the optical axes of both LEDs (4a, 4b) substantially impinge on the equilibrium member (3), and that the detector (5) is located on the side of the vial (1). 80788 BC Device according to claim 13, characterized in that two light sources such as LEDs (6a, 6b) are directed opposite the interface of the liquid of the vial (1) and the balance member (3) at the ends of the vial so that in the equilibrium position of both LEDs (6a, 6b) ) the optical axes substantially impinge on the balance member (3), and that the detector (5) is located below the balance member. Device according to Claim 13, characterized in that more than two light sources, such as LEDs (10a-10h), are directed laterally symmetrically in pairs from opposite directions to the liquid-balance interface of the circular symmetrical vial (7) so that each LED the optical axes of the diode pair (10a, 10e; 10b, 10f ...) substantially impinge on the balancing member (9), and that the detector (11) is located below the balancing member. Device according to claim 12, characterized in that a single light source such as an LED is directed at the interface between the liquid of the vial (1; 7) and the balance member (3; 9), and in that the device comprises at least two detectors with light beams reflected from the balance member. detectable. Device according to claim 18, characterized in that a single light source such as an LED is directed laterally at the liquid-balancing interface of the vial (1) and that below the vial there are two detectors arranged substantially symmetrically on the balance axis (1) of the vial (1). A). li i7 80788 Device according to Claim 18, characterized in that a single light source, such as an LED, is directed at the liquid-balancing interface of the vial (1) from below, and that on the side of the vial there are two detectors arranged substantially symmetrically in the plane of the vial (1). relative to the weight axis (A). Device according to Claim 18, characterized in that the two light detectors are directed opposite the interface of the liquid and the balancing element (3) of the vial (1) at the ends of the vial, and in that there is one light source such as an LED below the vial. Device according to claim 18, characterized in that more than two light detectors are directed laterally symmetrically in pairs from opposite directions to the liquid-balance interface of the circularly symmetrical vial (7) so that in the equilibrium position the optical axes of each detector pair hit the balance (9) symmetrically, and that the light source is located below the balancing member. 80788 BC