DE3230240A1 - Device, especially instrument, for the measurement of the positions and positional changes of joints and of the spine (arthrospinometer) - Google Patents

Abstract

An instrument for the measurement of the positions and positional changes of joints and of the spine (arthrospinometer) in which a dip circle in combination with a compass and an angular degree division related both to the circle and to the compass are arranged in a common housing, the angular degree division being rotatable relative to the housing, the housing being rotatably hinged between the arms of a fork-shaped holder, so that an axis of rotation of the housing, relative to the fork-shaped holder, extends at right angles to a common axis of the indicators of the combination of dip circle and compass, the fork-shaped holder being rotatably hinged to a base plate, one axis of rotation extending between the fork-shaped holder and the base plate at right angles to the axis of rotation between the housing and the fork-shaped holder and to the base plate.

Description

description

Device, in particular an instrument, for measuring positions and Changes in the position of joints and the spine (arthrospinometer) The invention relates to a device, in particular an instrument, for measuring the positions and changes in the position of joints and the spine; this as an arthrospinometer designated instrument can preferably be used in the therapy of the locomotor organs will.

In all medical fields dealing with the musculoskeletal system ' and deal with disorders of the locomotor organs, has the exact measurement of angular displacements the joints are of paramount importance. For this reason, a joint angle meter is used (Goniometer) with two arms, which are hingedly connected to each other, in used extensively. For example, it is used to measure the elbow joint placed one of the arms of the goniometer on the axis line of the forearm while the other is placed on that of the upper arm, and the pivot joint is opened the elbow joint aligned. The relative position of the gonaometer arms can be read from an angular graduation fixed on one of the arms.

However, it is very difficult to get the arms and pivot joint of the goniometer in exact alignment with the axis lines of the forearm, des Hold the upper arm and the elbow joint to carry out the measurement. The least Inaccuracy leads to heavily falsified measurements. A diseased elbow joint is mostly swollen or gummy and inflamed, making it nearly impossible to to find the real elbow joint. As is known to orthopedic surgeons the goniometer accurate when the limb boundaries are well defined. if however the limiting ends of the bones are not clear because they are through too much soft material are covered, the goniometer delivers imprecise values. In these In these cases, the trained surgeon can more accurately determine the joint angle without using the goniometer to adjust.

The disadvantages of the goniometer include not only the limited accuracy, but also that there are numerous joint positions and posture changes or - there are shifts that cannot be measured with its help.

For example, the components of the movement of the shoulder joint or the hip joint measured with great difficulty, if at all will. In order to eliminate the disadvantages of the goniometer, a measuring instrument was made developed, which combines a circle of inclination (inclinometer) and a compass. During the measurement, the instrument is attached to a band like a wristwatch Patient fixed. The shifts or changes in position in the vertical plane are measured by the incline circle and in the horizontal plane by the compass. With this instrument, however, only the angular range of displacement or change in position can be made of the joint can be measured, but not the contracture that occurs in clinical Practice is extremely important. If the examined person is healthy, they can do it Extend the leg fully. In this position the instrument is set to the value 0 set. The patient bends his leg completely. The protractor is read and the result shows the bending angle of the hip joint.

However, if the patient is sick and does not fully straighten his leg can (i.e. if he has a flexion contracture of the hip joint), the instrument can do not show the angle of the contracture. This is very detrimental to the patient with disorders of the locomotor organs almost always have some kind of contracture and also The measurement of the contracture is very important for clinical treatment and for the function of the organ.

This feature can be demonstrated on a patient, for example who can fully straighten his legs but only bend them up to 900 can. His hip joint is in far better condition than anyone else's A patient who cannot stretch his legs completely, but only up to 200, who however, it can bend up to 1100.

In both cases the known measuring instrument shows a shift or change of position by 90 °, namely the difference between 0 and 90 ° and between 20 and 110 ° both in the first patient, who is almost healthy, and in the second, who is sick.

Another disadvantage of the known type of instrument is shown, if the shift or change in position is not vertical or horizontal Plane remains, i.e. represents a spatial movement. When taking measurements at the shoulder joint For example, the upper arm is not only raised, but also rotated and the original vertical plane of the incline circle is none at the end of the movement vertical plane more. This falsifies the reading.

The known instrument fixed to part of a limb shows the actual angle of displacement or change in position of an examined Joint when the other limb part is in place without any movement is being held. If the displacement or change in position of the knee joint with is measured with an instrument fixed to the shin, the thigh may during the Rotation of the knee joint does not change its position.

However, this is the case with an examination as it is common today almost impossible.

The main disadvantage of this known type of instrument is that it is not used for measurements on the spine, which is considered to be a special type of joint can be viewed kanh, can be used. However, the backbone is the most important Part of the musculoskeletal system and therefore is the measurement of its position and displacement or change of position is a central question of medicine, which deals with the organs of the Movement system concerned.

The orthopedic surgeon is also aware of the actual Movement of the spine is very difficult with the help of physical examinations can be measured, since the backbone is covered by soft parts, normal curvatures and the movements in different parts of the spine with one another are combined.

Man can move only by moving the hip joint and without any Movement of the spine up to 900 forward, it has been found that the Inclination movement of the spine can be measured very accurately with the help of a Steel or plastic measuring tape. With this measurement method, the changing distance becomes between the first sacral vertebra and the seventh cervical vertebra measured and this is used to determine the extent of the forward flexion of the spine closed.

In contrast to this well-known method, the following six should Movements can be demonstrated separately: bending forward (bending), leaning back (Stretching), bending to the right, bending to the left, turning to the right and the turn to the left. This method also changes the distance measured, which depends on the patient's measurements, i.e. different ones are obtained Values in different patients. This measurement sung is also through influences the natural curvatures of the spine, for example the lumbar lordosis.

Another instrument for making measurements on the spine is the commonly known so-called Dunham-type spondylometer. It works like a pair of compasses and to carry out the measurement, the base plate of the The compass legs of the instrument are placed on the sacrum according to the graduation provided, the end of the other circular leg is against the spinous process of the seventh cervical Vertebrae pressed. The change in angle is determined by the graduation on Read the end of the patient's leaning or leaning back.

In this way, only two movements of the six above can be made Movements can be measured using the Dunham-type spondylometer. The basic principle this instrument assumes that the distance between the sacrum and the seventh cervical vertebrae do not change during the curvature of the spine. This postulate only applies to a stiff, numb spine. A stiff one However, the spine is unable to bend in any type of movement. The backbone is of course not stiff in reality, so the change the distance between the sacrum and the seventh cervical vertebral bone the measurement result obtained with the Dunham-type spondylometer is falsified.

In addition, the sacrum is not the same in all patients Shape so that the edge of the base plate of the Dunham-type spondylometer does not appear all sakra fits.

The aim of the present invention is therefore to remedy the above-mentioned shortcomings to eliminate or weaken the known measuring instruments. For this reason should allow a simple, reproducible and objective measurement to be carried out the positions and shifts or changes in position of joints or the spine a universal instrument to be created.

The basic idea of the present invention is that the displacements or changes in position in relation not only to the body of the examined patient, but should also relate to an external stable reference point. For movements in the vertical plane this reference point is the gravitation with one to the center the earth-pointing attraction, which is therefore always vertical. For movements in the This reference point is the earth's magnetic field with the stable horizontal plane North-south direction. The movements in space or in planes other than the horizontal or vertical plane should be in movements in the vertical or horizontal Level to be transformed.

The instrument according to the invention differs from the one mentioned above known combination of an inclination circle and a compass in that the Housing that contains the inclinometer, the compass and the 'angular graduation, which is related to both the incline circle and the compass, between is rotatably articulated to the arms of a fork-shaped holder, the axis of rotation of the housing relative to the arms perpendicular to the common axis of the pointer of the Combination of slope and compass runs. Furthermore, the fork-shaped holder rotatably hinged to the base plate. The axis of rotation between the fork-shaped holder and the base plate is perpendicular to the axis of rotation between the housing and the Arms of the holder as well as to the base plate.

The angular graduation in the housing can be based on its two circumferences, i.e., the outer and inner circumference, have scales.

The axis of rotation between the arms of the fork-shaped holder and the Housing can be formed by axle journals that are fixed to the arms and are rotatably hinged to the housing.

For attaching the instrument to a patient to whom the Measurements should be carried out, for example on the forearm, upper arm, leg or on the Spine, a rubber band can be fixed to the base plate.

An angular graduation can be provided on the base plate, which indicates the rotation of the fork-shaped holder relative to the base plate.

Both angular degrees, i.e. the one in the housing and the one on the base plate, can be made as two mirror-symmetrical semicircles with scales of 0 to 1800 and the semicircles can be different colors be different from each other.

To improve the reading of the angle value when turning the fork-shaped holder on the angle graduation provided on the base plate can be a pointing edge, which shows the center plane of the fork-shaped holder and is related to the angular graduation, be provided.

The instrument should be firmly attached to the patient during the measurement without slipping or shifting.

A suction cup can be attached to the base plate for this purpose. In a very simple embodiment, the base plate can have a central opening have on their side opposite the fork-shaped holder, and the central pin of the suction cup can be fixed in this central opening. It it is advantageous if the central plane of the suction cup runs parallel to the base plate.

Situations are conceivable in which the instrument fixed to the body gets into the trajectory. It can be between the central peg of the suction cup and the central opening of the base plate is an adjustable length extension be provided to prevent this.

The invention is described below with reference to enclosed Drawings explained in more detail, but without being limited thereto. They show: Fig. 1 shows a side view of an embodiment of the instrument according to the invention; Fig. 2 is a plan view of the embodiment according to FIG. 1; Fig. 3 is a perspective View of the embodiment shown in Figure 1; 4 shows an examination of the knee joint and the hip joint with an embodiment of the instrument according to the invention; 5 shows an examination of the hip joint in another patient; Fig. 6 a Examination of the neck with the instrument according to the invention; Fig. 7 is a side view an examination arrangement with the instrument according to the invention; 8 shows a spinal examination with the instrument according to the invention; and FIG. 9 shows another embodiment of the Instrument according to the invention fixed on the neck of a patient.

1 to 3 is an exemplary embodiment of the invention Instruments shown in different views. As can be seen from this, the Basic unit of the instrument a combination of an inclination circle (inclinometer) and a compass represented by the reference number 1. The slope circle has a freely movable pointer 2, whereby the pointer 2 is always in the different tical Position shows when the incline circle is in the vertical plane or in the Near the same. The compass of the unit 1 has a compass needle 3, which, as usual, points in the north-south direction when the compass is roughly in the horizontal plane. The pointer 2 and the compass needle 3 have one thing in common Axis of rotation 4.

In this way the same instrument can be used for measurements in the vertical plane as well as the horizontal plane can be used. A common Graduation 5 is related to both the slope circle and to the compass of unit 1. The graduation 5 consists of two mirror-symmetrical Semicircles 6 and 7, with both semicircles 6 and 7 graduated from 0 to 1800 exhibit. The semicircles 6 and 7 are distinguished from each other by two colors, for example, the semicircle 6 is red and the semicircle 7 is green.

The unit 1 with the inclination circle and the compass as well as the angular graduation 5 are installed in a common housing 9. The angular graduation 5 can be rotated relative to this housing 9 at 8. The housing 9 is through axle journals 10 and 11, which are fixed to the arms of the holder 12, rotatably attached to the arms of a fork-shaped holder 12 articulated. The axle journals 10 and 11 are in a line, which runs perpendicular to the axis of rotation 4 of the pointer 2 and the compass needle 3. on in this way the housing 9 can be freely rotated between the arms of the holder 12, however, it remains in the position in which it was set. To this Purpose, for example, the pins 10 and 11 are firmly fitted into the housing 9.

The fork-shaped holder 12 is rotatably linked to a base plate 14 with an axle journal 13 that is perpendicular to the base plate 14 and to the axle journal 10 and 11 of the fork-shaped holder 12 extends. Similar to pins 10 and 11 In the housing 9, the axle journal 13 is also firmly in the fork-shaped holder 12 fitted so that it allows its free rotation, but in its position, in which he has been set remains. With this arrangement, the combined Unit 1 can be set to any spatial position after the Instrument according to the invention has been attached to the patient.

A rubber band 15 is attached to the base plate 14 for fixation of the instrument on the patient to be examined. On the base plate is also an angular graduation 16 is fixed for reading the rotation of the fork-shaped holder 12 relative to the base plate 14. The angular graduation 16 consists of two mirror-symmetrical Semicircles, each graded from 0 to 1800. The line, which connects the points O0 and 1800 with each other, runs perpendicular to the longitudinal axis of the elastic band 15. The semicircles of the angular graduation 16 are different Colors differ from each other, for example one is red and the other green.

The fork-shaped holder 12 has a pointing edge 18, which as Extension of the central plane of the holder 12 is formed. The pointing edge 18 is standing in relation to the angular graduation 16, i.e.

it turns together immediately above the graduation 16 with the holder 12. In this way it shows the rotation of the fork-shaped holder 12 at.

A suction cup 21 is attached to the base plate 14 on its side, which is opposite the fork-shaped holder 12 to a displacement of the instrument on the patient on whom the measurement is to be carried out.

For this purpose there is a central opening 20 in the base plate 14 provided with a central pin 22 of the suction cup 21, for example a releasable connection is connected.

The plane defined by the circumference of the suction cup 21 or its center plane runs parallel to the base plate 14. The central pin 22 of the Suction cup 21 can have varying lengths for different examination areas.

Sometimes the instrument attached to the patient can get into the movement path of the examined object.

Therefore, an extension rod 23 can be detachable between the central Pin 22 of the suction cup 21 and the central opening 20 of the base plate 14 are provided be. The length of the extension rod 23 can be used for various research purposes be adjustable.

The function of the illustrated in FIGS. 1 to 3 according to the invention Instruments is described in more detail below with reference to the other figures. As can be seen from this, the axis of rotation formed by the axle journals 10 and 11 runs always parallel to the base plate 14, so that the position of this axis of rotation is directly from the angular graduation 5 of the unit 1, for example on its outer circumference, can be read. This value also gives the relative position of the base plate to the vertical direction (circle of inclination) or to the north-south direction (compass) at.

When examining the organs of the musculoskeletal system, measurements should be taken preferably have an accuracy of 50. In some special areas of the Examination, for example of the spine, is an accuracy of 2 or 30 desirable because of the diagnostic consequences on the one hand and the evaluation of the different therapies on the other hand.

In FIG. 4, a lower limb of a patient is in an examination position shown. The central axes of the thigh and tibia are indicated by dashed lines Lines shown. In the principle of measurement it is of great importance that the limbs have an approximately cylindrical or conical shape and that the through The axes shown in dashed lines are their central or symmetry axes. The instruments are fastened with the elastic band 15, that about perpendicular runs to the axis of the limb, attached to the limb. Thereby one runs Line showing the point 0 ° and the point 180 ° of the angular graduation 16 of the base plate 14 connects, measured parallel to the axis of the limb.

The investigation is carried out as follows: In FIG. 4, the Hip joint measured using an instrument according to the invention that is attached to attached to the leg. According to today's neutral-zero method, the starting position is i.e. the neutral or zero position of the hip joint is that in which the thigh is fully stretched out. In this examination, the inclination circle (inclinometer) of unit 1 is used, i.e. it is measured in the vertical plane. To this The purpose is the O0 setting of the angular graduation 5 of the unit 1 on the pointer 2 of the incline circle in the initial extended position of the leg turned. The leg is then bent to its other end position, whereby read off the angular value indicated by the pointer 2 on the angular graduation 5 will. This angle value directly reflects the flexion of the hip joint.

If one now assumes that the patient is not healthy, then he has a so-called flexion contracture of the hip joint, i.e. he can use his thigh do not fully stretch so that the neutral position cannot be reached. In this position of the thigh, stretched as far as possible, becomes the index edge 18 of the fork-shaped holder 12 in the # 0 position on the angular graduation 16 of the base plate 14 rotated. As a result, the line of the axle journals runs 10 and 11 parallel to the central axis of the leg. The slope circle is made by turning the angular graduation 5 is set on the pointer 2 to the value O and the value of the angle on the journal 10 on the outer circumference of the angular graduation 5 is displayed, is read. After subtracting this value from 900 you get the value of the angle of the contract tur, because the angle between the healthy (fully extended) limb and the vertical limb is 900.

Another instrument is also used to examine the knee joint fixed on the shin as shown in FIG. 4.

When the knee joint of a sick patient has a flexion contracture the angles between the vertical axis and the central axis of the Thigh and tibia are measured. To this end, the instruments set to the value 0 as described above in connection with the hip joint (the pointing edge 18 points to the value 0 on the angular graduation 16, the value O the Graduation 5 on pointer 2 of the inclination circle). The values are on read the outer circumference of the angular graduation 5. The sum of these angles is the contracture of the knee joint.

The different colors of the semicircles play a role in this measurement the angular graduation 5 a role. As can be seen without further ado, is considered to be general Rule of this instrument that when the angles are in semicircles with different Colors are represented, these are added, and that, in contrast to this, they are then if they are shown in semicircles with the same colors, are subtracted.

One instrument is all that is needed to measure the rotation of the knee joint off when the thigh is fixed and no displacement during the examination occurs. When two instruments are fixed as shown in Fig. 4, the move the thigh as well. The instruments are based on as described above the value 0 is set and that of the angular graduations 5 of the instruments read values are summed up at pointers 2 depending on the colors of the semicircles or subtracted.

In practice, the abduction and the abduction of the hip joints must also be performed which are the Distance movement and the movement of approaching the midline of the body through the thigh is. The unit 1 is on a plane parallel to the so-called frontal plane of the body set. This can easily be done as the unit 1 can be converted into any spatial position can be brought because the axis of rotation on the axis 4 to the Axle journals 10 and 11 and on the journal journals 13 each spatially perpendicular to one another get lost. The instrument is attached to the thigh and in the neutral position of the hip joint is set to the value 0. After that, the maximum abduction can be achieved corresponding angular values and the maximum abduction itself directly from the angular graduation 5 can be read.

The unit's compass is used to measure the rotation of the hip joint 1 is used, as explained in FIG. 5. The unit 1 is in the horizontal And by turning the angular graduation 5 on the compass needle 3 in the neutral position of the hip joint is set to the value O. After turning of the leg outwards and inwards are the angular values of the angular graduation 5 read on compass needle 3. If the unit 1 fails at the end of the rotation more in the horizontal plane, this can be corrected without difficulty what is necessary for an accurate measurement with the compass.

The angular graduation 16 is used for stronger contractures, which limit the ability of a joint to move. The contracture during abduction as well as the abduction itself can be performed with an accuracy of 10 are measured when the instrument is fixed on the anterior surface of the thigh. The unit 1 is set to the frontal plane for which the pointing edge 18 from Value 0 of an angular graduation 16 is rotated away. The values 00 and 1800 However, the connecting line is still parallel to the central axis of the leg.

On pointer 2 of the inclination circle, which is in the frontal plane is located, the value 0 is the angular degree division 5 discontinued. In this way there is the difference between the angle AB (Fig. 5) on the angular graduation 16 of the base plate 14 and the angle CD, which is of the angular graduation 5 at the Axle journal 11 is read, the angular value between the axis of the leg and the vertical, i.e. the exact value of the contracture at the abduction of the hip joint at. In this case too, those must be read from semicircles with the same color Values are subtracted.

As described in detail above, the problem was measurement the positions and shifts or changes in position of the spine so far unsolved. The principle of the measurement is shown in FIG. 6, in which the Examination of the cervical spine is discussed. At the end points of this An instrument according to the invention is fixed on part of the spine, i.e. on the Head of the patient and above the seventh cervical vertebra. To carry out This measurement uses the inclination circle of unit 1 and unit 1 is set in a plane that is perpendicular to the frontal plane and vertical to it is. The instruments are turned by turning the value O of the angular graduation 5 on the pointer 2 set to 0 in the neutral position of the spine. To the forward bend, the pointer 1 run over the angle fields of the angular degrees 5 as shown by the hatched lines in the figure. The instrument H in 6 shows the displacement or change in position of the body, while the Instrument G the displacements or changes in position both of the body and of the neck.

The difference between these two values gives the exact diffraction angle the cervical spine.

With the same arrangement, the elongation (recoil) of the cervical spine are measured.

The lateral flexion of the spine (to the left and to the right) with the in a plane parallel to the frontal ne set Instruments measured.

The rotation of this part of the spine is done with the compass needle 3 and thus measured with instruments set on the horizontal plane are.

With four instruments according to the invention, all three parts of the Spine, namely the cervical part, the dorsal part and the lumbar part, measured separately, independently of one another or in any combination with one another will. The instruments are attached to the body with rubber bands 15. That lowest instrument is attached to the surface of the sacrum, that with others Parts of the pelvis are firmly connected, so that the movements of the hip joint can be subtracted from the angle with that on the last dorsal vertebral body fixed instrument is measured. In this way, the displacements or Changes in position which falsify the measurements are eliminated.

As stated above, not only the displacements or Changes in position, but also the positions, the static form and the existing ones Curvatures of the spine are measured. This is possible because the line the axle journals 10 and 11 always run parallel to the base plate 14. In Fig. 6 runs the base plate 14 of the instrument F, which is on the last cervical vertebral body parallel to the axle journal 10.

After setting the value 0 of the angular graduation 5 on the pointer 2 of the inclination circle can be the angle between the vertical and the lower part of the cervical spine from the angular graduation 5 on the axle journal 10 can be read.

In Fig. 8 is the lateral curvature (scoliosis) of the spine shown. After attaching the instrument with a rubber band 15 on the to be measured part of the spine is the pointing edge 18 of the fork-shaped Halters 12 rotated to align with the curved portion of the spine. The angle of the curved part with respect to the vertical can depend on the graduation 16 of the base plate 14 on the pointing edge 18 or on the angular graduation 5 of the Inclination circle in unit 1, which runs in a plane parallel to the frontal plane, can be read.

To measure the forward or backward flexion of the spine (Kyphosis or lordosis) the pointing edge 18 is set to the value 0 on the angular graduation 16 is set, the value 0 of the angular graduation 5 of the unit 1 is set to the Axle journal 10 is set and the unit 1 is in a plane perpendicular to the frontal plane turned. In the case of kyphosis, the angle measured has that on the angular graduation 5 is read on the pointer 2 of the inclination circle, a positive value, while in the case of lordosis this value is negative.

In some cases, the instrument attached to the body can in be the path of movement. For example, this can be the case with the seventh cervical vertebral body the attached instrument collide with the head bent backwards completely.

To prevent this, an extension rod 23 between ~ the Suction cup 21 and a base plate 14 may be used, as shown in FIG. 9. The extension rod 23 has an adjustable length and runs parallel to the base plate 14 as well as to the central plane or to the plane of connection with the suction cup 21. Through the insertion of the extension rod 23 thus does not affect the measurement.

The instrument according to the invention can be used in very different areas in medicine, in clinical practice in rheumatic diseases, orthopedics, ~ der-tråumato- ~ bogie and rehabilitation of the musculoskeletal system. Ankylopoietic spondyloarthritis can be recognized at an early stage by measuring the more or less strong rotation and lateral bending of the Spine.

In forensic medicine, the condition of the locomotor organs can be objective be measured. By measuring whether the shift or change in position of the spine If it is lower and asymmetrical, idiopathic scoliosis can occur at an early stage be recognized. In addition, new therapeutic methods can be accurately assessed and can be controlled by precise measurements with the instrument according to the invention.

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Claims (9)

Device, in particular an instrument, for measuring the positions and changes in position of joints and the spine (arthrospinometer) e k e k e n n n z i n e t by a slope circle, which in combination with a Compass and an angular graduation (5), based on both the inclination circle as well as on the compass is built into a common housing (9), the Angular graduation (5) relative to the housing (9) is rotatable between the Arms of a fork-shaped holder (12) is rotatably articulated, with an axis of rotation of the housing (9) relative to the fork-shaped holder (12) perpendicular to a common The axis of the pointer (2) of the combination of inclination circle and compass runs fork-shaped holder (12) is rotatably hinged to a base plate (14), wherein a The axis of rotation between the fork-shaped holder (12) and the base plate (14) is perpendicular to the axis of rotation between the housing (9) and the fork-shaped holder (12) as well to the Pasist ((14, 2. Device according to claim 1, characterized in that that the angular graduation (5) has scales on both circumferential edges. 3. Apparatus according to claim 1 or 2, characterized in that between the housing (9) and the arms of the fork-shaped holder (12) in the axis of rotation Axle journals (10, 11) are provided. 4. Device according to one of claims 1 to 3, characterized in that that for fastening the device to the object on which the measurement is carried out is to be, a rubber band (15) is fixed to the base plate (14). 5. Device according to one of claims 1 to 4, characterized in that that an angular graduation (16) is provided on the base plate (14). 6. Apparatus according to claim 5, characterized in that both Graduations of degrees of the housing (9) and the base plate (14), the two mirror-symmetrical Have semicircles with scales from 0 to 1800, the semicircles by different ones Colors are different from each other. 7. Device according to one of claims 1 to 6, characterized in that that the fork-shaped holder (12) has a pointing edge (18) which has a central plane of the fork-shaped holder (12) and on the angular graduation (16) the base plate (14) is related. 8. Device according to one of claims 4 to 7, characterized in that that the base plate (14) has a central opening (20) on its fork-shaped Holder (12) opposite side a central pin (22) of a suction cup (21), which is fixed in its central opening (20), the central plane of the suction cup (21) is parallel to the base plate (14). 9. Apparatus according to claim 8, characterized in that between the central pin (22) of the suction cup (21) and the central opening (20) of the Base plate (14) an adjustable extension rod (23) is provided.