FI79906C - Device for indicating an angle or direction - Google Patents

Description

79906

DEVICE FOR INDICATING ANGLE OR DIRECTION - ANORDNING FÖR ANGI -VANDE AV EN VINKEL ELLER RIKTNING

The present invention relates to a device for detecting a desired angle or direction, which device comprises an elongate body part and at least one tilt-sensitive vial attached thereto.

Especially on construction sites, a lot of vertical measuring equipment is used to check the verticality of walls and structures and to define lines. The most common devices are a spirit level and a bullet wire. The latest technology is represented by laser applications based on distance measurement.

All known solutions have a narrow range of applications. The accuracy of a ve scale strongly depends on its user, and it is not suitable for determining lines, which is a suitable task for bullet wire, but which usually (ceiling-floor alignment) requires two people to succeed. Normally, a spirit level can check up to vertical and horizontal levels, while bullet wire is not suitable for anything other than vertical checking. Laser equipment is expensive and cumbersome to use. Their use does not make sense except in a vertical check (there must be smooth surfaces!), And: each check requires at least two measurements (distance measurement).

The object of the present invention is to provide a simple, versatile and single-person direction-checking device which does not have the above-mentioned disadvantages. For a device according to the invention, which device comprises an elongate body part and at least one tilt-sensitive vial attached thereto, the position of the vial being arranged to be monitored by detector electronics and indicating by means of an audible, light or other similar signaling device a gas bubble in the vial is in its center position and the desired direction is reached, 2 79906 is thus mainly characterized by a light source (D1) directed at the center of the vial from a certain angle to the vertical axis to observe the gas bubble T1) by means of detector1 electronics.

The advantage of the device according to the invention is, firstly, that its user does not have to observe any organ to assess when the desired direction has been reached, but the device itself and accurately reports it. In this case, the employee can handle the device alone and focus on setting up the device correctly. Second, the measurement results are more comparable, and the results of properly prepared measurements do not depend on the professional skill of the user.

Practical experiments have shown that the reflection surface formed by a gas bubble in a liquid acts as a fairly accurate mirror, whereby even the slightest movement of the bubble around the equilibrium point significantly affects the intensity of the reflected light. An integrated component with a light emitting diode and a photosensitive transistor at an angle of e.g. 45 ° can advantageously be used for monitoring the gas bubble of the vial. Thus, this type of measuring device 11 quite provides: * an accurate detection device.

A preferred embodiment of the method according to the invention is also characterized in that the sound-sensitive member is attached to the body part in an articulated manner so that the measuring element unit can be pivoted and locked in place at a desired angle to the body part for different inclinations and vertical and horizontal planes. .

With such a simple operation, the detector device becomes truly versatile. Very often, for example, in the manufacture of larger molds and models, there are levels and supports of 3,79906 m, the slopes of which are completely arbitrary and for which high accuracy requirements are set. Prior to these angles, it has been necessary to check indirectly by calculating from a piece already made, which makes repairs difficult.

A preferred embodiment of the method according to the invention is further characterized in that the body part of the device comprises at least one pull-out extension part, i.e. an extension arm, and that the other end of the body part thus formed has a bent disc spring, a sprung wheel or a similar sliding member. For example, when moving a line from the roof of a room to the floor, two people and a bullet wire have been needed in the past. By extending the device according to the invention sufficiently, placing the measuring tip at the other end of the device on the roof line mark and moving the lower end of the device along the floor using a slider until an audible or visual signal is given, alignment can be easily and accurately performed by one person.

A preferred embodiment of the method according to the invention is further characterized in that the measuring surface of the body part has two or more rods projecting from the surface, and that a suspension bracket is arranged at one end on the measuring surface side holding the body part against the surface to be inspected. This version is especially suitable for checking the vertical position of concrete and other elements with a rough surface during building construction.

The invention will now be described in more detail by way of example with reference to the accompanying drawing, in which

Fig. 1 shows an embodiment of a vertical measuring device according to the invention,

Fig. 2 shows another embodiment of a direction indicator according to the invention,

Fig. 3a shows an embodiment of a sensor used in the device according to the invention.

4,79906

Fig. 3b shows the angular change response curve of the sensor according to Fig. 3a.

Fig. 4 shows an example of the detector electronics used in the device according to the invention.

As shown in Fig. 1, the basic solution of the device according to the invention consists of an elongate body part 1, a tilt-sensitive measuring element 2 attached to it and additional application-specific structures, in this case a suspension bracket 3 and houses 4. The device is used to place e.g. a concrete element 5 vertically. Instead of following the movements of the bubble in the small vial, an audible signal is now expected when the device according to the invention is used, whereby the adjustment of the position of the element 5 is stopped.

Figure 2 shows a device according to the invention, to which several means have been added in order to diversify the use of the device. According to the figure, it is possible to use the device to move a line e.g. from roof to floor by placing a sharp spike 10 against the line mark in the roof 6, extending the body 1 by the telescopic extension 8 with the locking screw 11 so that the sliding spring 9 reaches the floor surface 7, and moving the slider 10 repeatedly pressed against the line mark until the beep sounds. In this case, the alignment device is vertical and the line is moved from the roof to the floor. The extension part 8 may also consist of several nested parts (not shown). If it is desired to move the point, the alignment must be performed in two different directions, whereby the intersection of the moved lines is the desired point, or by providing the measuring element 3 with two tilt-sensitive sensors perpendicular to each other in the same plane.

In the embodiment of the invention according to Fig. 2, the measuring member 3 is hinged to be pivoted by a hinge 12 to the center of a semicircular plate 13 the position of the second side of the measuring element 3 relative to the scale plate 13. The measuring element can be locked in the desired position during the measurement. Equipped in this way, the device according to the invention can be used to determine the angle of a plane in any direction with respect to a horizontal or vertical plane.

Figure 3a shows a solution for detecting an inclination based on a spirit level 14 traditionally used in spirit levels. The air bubble 15 in the spirit level forms a mirror surface which reflects the light from the infrared diode in the reflection circuit 16. When the center of the air bubble 15 is at the intersection of the optimal light paths of the transmitter (e.g. infrared diode) and receiver (e.g. phototransistor) of the reflection circuit, the mirror reflects light from the transmitter symmetrically to the mirror surface normal, causing the strong reflection light to If, on the other hand, the center of the air bubble 15 deviates slightly from the intersection of said directions, the light is reflected substantially past the receiver.

The intensity of the reflected light is registered in the electronics unit 17, which determines whether the bubble 15 is in the middle of the vial 14 or not. If the bubble is in the center of the vial, this is indicated by giving an audible, light, etc. signal. The level 14, the reflection circuit 16, the electronic unit 17 and its signaling device 18 can together form the above-mentioned detector circuit 2.

Fig. 3b shows the experimentally obtained angular change response curve of the sensor of Fig. 3a. It has been found that even if the resolution of the device is limited to the intensity peak alone, the accuracy is still at least 0.5 degrees. However, the detection limit can be easily selected as desired, two detection limits I and II can also be selected according to the figure, which correspond to angular distances oCi and OCII * In this case, it is possible to give an approach signal in the form of an increasing intermittent sound when approaching the angular range oCi U the detected detection limit I is given a continuous signal. The detection limits can also be interpreted as two acceptance limits corresponding to different accuracy classes.

Fig. 4 shows by way of example the electronic unit 17 of the detector circuit shown in Fig. 3a. Its operation is as follows:

When the air bubble in the vial is not within the radius of the reflection circuit, the reflection of the light from the light emitting diode D1 to the light transistor T1 is negligible. As the bubble moves into the beam region, the reflection intensifies, reducing the voltage level at point X and below the voltage level at point Y. The operational amplifier 21 then controls the oscillator 19, which, amplified by transistor T2, produces a cut-off sound in buzzer 18 As the bubble moves further towards the center of the vial, the reflection angle improves and the voltage level at point X falls below the voltage level at point Z. In this case, the operational amplifier 20 gives the transistor T2 control for a continuous buzzer signal (accuracy range I).

By selecting the voltage levels at points Y and Z appropriately, the desired accuracy is obtained for the detector device. Capacitors C1 and C2 eliminate the effects of mechanical vibrations in the switching phase.

It will be clear to a person skilled in the art that the various embodiments of the invention are not limited only to the example given above, but may vary within the scope of the claims set out below.

Claims (5)

7 79906 A device for indicating a desired angle or direction, the device comprising an elongate body portion (1) and at least one sound-sensitive vial (14) attached thereto, wherein the position of the vial (14) is arranged to be monitored by detector electronics (17) by means of a connected sound, light or other similar signaling device (24) indicates that the gas bubble (15) in the vial is in its central position and the desired direction has been reached, characterized in that the gas bubble (15) in the vial (14) is a light source (D1) oriented with respect to the vertical axis, the intensity of the reflection of which is detectable by a light-sensitive sensor (T1) arranged symmetrically with the light source with respect to the vertical axis by means of detector electronics (17). Device according to Claim 1, characterized in that an integral component (16) with a light-emitting diode (D1) and a photosensitive transistor (T1) is used to monitor the gas bubble (15) of the vial (14). Device according to Claim 1 or 2, characterized in that the tilt-sensitive element is fastened to the body part (1) by a hinge (12) so that the measuring element unit (2) can be pivoted along the angle scale (13) to the desired angle to indicate different angles to the part (1). Device according to Claim 1, 2 or 3, characterized in that the body part (1) of the device comprises at least one pull-out extension part (8), i.e. an extension arm, and that at one end of the body part thus formed there is a bent spring (9), spring wheel or similar sliding member. Device according to one of Claims 1 to 4, characterized in that the measuring surface of the body part has two or more rods (4) projecting from the surface, and in that at one end a suspension bracket (3) is arranged on the measuring surface side, holding the body part (1). ) pressed against the surface to be checked. 8 7 9 9 06