WO1998023447A1

WO1998023447A1 - Clinometer, clinometric system and operating procedure for aligning machines in the polygraphic industry

Info

Publication number: WO1998023447A1
Application number: PCT/DE1996/002256
Authority: WO
Inventors: Michael Bernhard
Original assignee: Michael Bernhard
Priority date: 1996-11-23
Filing date: 1996-11-23
Publication date: 1998-06-04
Also published as: AU1590597A

Abstract

The present invention relates to a clinometer (10, 32) comprising a contact body (12, 34) provided with an electronic slope sensor (30, 50). It can be associated with an assessment unit which processes a clinometric signal from the slope sensor (30, 50). The clinometric facility includes at least one clinometer (10) for the horizontal inclination of the cylindrical axis and at least two clinometers (32) for the vertical inclination of the surfaces intended for ancillary equipment (60). The process mainly consists in the simultaneous computer-controlled processing of the clinometric signals (64).

Description

Inclinometer, inclinometer and method for using it for aligning machines in the graphics industry

description

The invention relates to inclinometers, an inclinometer with several of these inclinometers and a method for their use for aligning machines in the graphics industry, in particular printing machines.

A series construction is known for such machines, in which modular components, for example printing units, follow one another in the longitudinal direction. The components usually have side stands that extend in the longitudinal direction on both sides, and transversely oriented cylinders mounted between the side stands. Flat mounting surfaces are usually provided on the front of the side stands, on which the next component can be aligned and installed. The components usually stand on height-adjustable leveling feet at their four corners.

When installing or reinstalling a machine of the type mentioned, the components must be aligned. This is done component by component. First, the rearmost component is aligned by adjusting its leveling feet so that the axes of their cylinders are horizontal and their mounting surfaces are oriented vertically. Then the next component is attached to it, in turn aligned accordingly, u. s .w. Precise alignment is essential for machines of the type mentioned. If the alignment is not guaranteed or is lost, for example because the floor on which the machine is standing lowers, vibrations occur in the machine run and the register accuracy is impaired. Print quality drops in printing machines. This may result in the need to disassemble and realign the machine. In view of the associated effort and machine downtime, the question arises as to the cause of the inaccurate alignment.

Machines in the graphics industry are traditionally aligned with frame spirit levels. These have a frame-shaped contact body that is attached to the machine and a spirit level that is filled with liquid except for a small gas bubble. The gas bubble is exactly in the middle with the horizontal or vertical position of the spirit level and shows

Deviations from this with an accuracy of approx. 0.02 mm / m.

The well-known alignment of machines in the graphics industry with frame spirit levels is a rather cumbersome and lengthy process. Since the height adjustment of a leveling foot influences the inclination of the machine lengthways and crossways, it takes professional experience to make the correct setting. Even a specialist only gradually approaches the correct setting of the leveling feet.

The Rahmeri spirit levels must be placed at the top of a cylinder or at the front on the mounting surfaces of the machine, while the leveling feet are operated at the bottom. A fitter can therefore usually not directly observe the influence of his positioning work. Several people must therefore work, some of whom have their spirit levels in mind and some of whom adjust the leveling feet. Frame spirit levels are quite sensitive to temperature, slow and limited in their accuracy. Reading the spirit level of a frame spirit level is not free from subjective influences.

There is currently no reliable documentation of the alignment. If there are malfunctions due to inaccurate alignment, the cause can often not be determined. So that the one who has carried out the alignment can come to a proof that no assembly error, but z. B. is a cause of the imprecise alignment for which he is not responsible.

The object of the invention is to provide inclinometers, an inclinometer with several of these inclinometers and a method for their use for aligning machines in the graphics industry, in particular printing presses, which enable less tedious and personnel-intensive, faster, more precise and documented documented alignment .

Similar to the known frame spirit levels, the inclinometers that solve this task have a contact body that can be attached to the machine to be aligned. The contact body is equipped with an electronic tilt sensor. The inclinometer is connected to an evaluation unit which processes an inclinometer signal from the inclinometer.

Electronic inclination sensors are available which detect inclination deviations from the horizontal or vertical with an accuracy of approx. 1 _ι / m and deliver a corresponding inclination angle measurement signal. Examples include tilt sensors from the "ZEROTRONIC" series from Wyler AG, CH-8405 Winterthur, Switzerland. The measuring principle of these inclination sensors is based on the deflection of an between two electrodes suspended pendulum. The pendulum forms a differential capacitor with the electrodes. Due to the inclination of the contact body carrying the sensor, the pendulum is deflected and a change in capacitance is brought about, from which the inclination angle measurement signal results.

The inclination angle measurement signal is an objective quantity that can be evaluated mathematically and documented with evidence.

The evaluation unit processing the inclination angle measurement signal can be located at a location remote from the inclinometer, e.g. B. near a leveling foot to be adjusted. This enables the fitter to directly observe the influence of the leveling on the inclination of the machine. Alignment is thus potentially one-man work.

The computational evaluation of the inclination angle measurement signal can guide the alignment objectively and considerably simplify and accelerate it. Thanks to the high measuring accuracy of the inclination sensors, more precise alignment is possible than with frame spirit levels.

The inclination sensors mentioned are inherently less sluggish and sensitive to temperature than a frame spirit level. To use the latter for the high precision of the alignment, the contact body of the inclinometer according to the invention is preferably a solid metal body of high heat capacity and insulated against the heat of a hand holding the inclinometer.

In a design of the inclinometer, which is intended to be placed on a cylinder of the machine to be aligned horizontally, the contact body has a profile with two flat lower contact surfaces inclined at an obtuse angle and an inclination sensor for the horizontal inclination of the profile axis. The shape of the contact body enables tion measurement on cylinders of different diameters on which the contact body rests. The inclinometer has two equivalent measuring positions in which it is rotated by 180 ° with respect to a vertical axis. This enables an envelope measurement to calibrate the inclinometer. One brings it to the two measuring positions one after the other, measures the respective inclination and takes the mean value of the measurements as 0 ° horizontally.

In a preferred embodiment, the contact surfaces of the contact body form an angle of approximately 165 °. The inclinometer is therefore suitable for a wide range of cylinder diameters.

The contact body of the inclinometer can have a groove extending in the longitudinal direction of the profile at the apex of the contact surfaces. This is an advantage for simple manufacture of the contact surfaces.

In a design of the inclinometer, which is intended to be applied to a vertically aligned mounting surface of the machine, the contact body has at least a pair of spaced-apart contact shoes with flat contact surfaces which lie in a common plane and an inclination sensor for the vertical inclination of this contact plane.

A pair of contact shoes, the contact planes of which are parallel, are preferably provided on opposite sides of the contact body. This enables an envelope measurement to calibrate the inclinometer. To do this, he is brought into the measuring position in succession with one or the other pair of contact shoes, the respective inclination is measured and the mean value of the measurements is taken as 90 ° vertically. In a preferred embodiment, the contact shoes are magnetic holders which hold the inclination sensor on the mounting surface of the machine.

The inclinometer is preferably pivoted toward the mounting surface about its vertical axis in the measuring position. In a preferred embodiment, a handle is attached to the contact body above and below the contact shoes and in the middle between their contact levels.

In order to isolate the inclinometer from the heat of a hand holding it, the handles are preferably made of a material of low thermal conductivity, in particular plastic.

The inclination measuring system that solves the above-mentioned task includes / includes at least one inclinometer for placing on a horizontally aligned cylinder, at least two inclinometers for placing on a vertically aligned mounting surface and an evaluation unit to which the inclinometers can be connected at the same time and which processes their inclinometer signals simultaneously . The inclination measuring system allows the essential inclination parameters of a machine to be aligned to be recorded simultaneously and the influence of the adjustment of a leveling foot thereon to be determined simultaneously. Aligning the machine is so easy, quick and precise.

The evaluation unit is preferably a portable computer which enables program-directed alignment, preferably using a graphic display. A graphical display of the result of the electronic inclination angle measurement on the computer display is much easier to use and more precise than the level indicator of a frame spirit level. A printer can preferably be connected to the computer in order to be able to document the result of the alignment by means of a printout.

The method for aligning machines of the graphics industry, in particular printing machines, which have side stands, at least one cylinder with an axis to be aligned horizontally and mounting surfaces which are to be aligned vertically on the front of the side stands and stand on leveling feet and which stand on leveling feet, consists in the fact that a Inclinometer for the horizontal inclination of the cylinder and an inclinometer for the vertical inclination of the two mounting surfaces, the inclinometer is connected to the evaluation unit and the printing machine is leveled based on its simultaneous inclinometer signal processing.

In a preferred variant of the method, the inclinometers are initially calibrated by an envelope measurement.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawing. Show it:

Figure 1 is a front view of an inclinometer, which is intended to be placed on a horizontally aligned cylinder.

FIG. 2 shows a top view of the inclinometer with a view in the direction II of FIG. 1;

3 shows the side view of an inclinometer which is intended for attachment to a mounting surface which is to be aligned vertically;

Fig. 4 is a front view of the inclinometer looking in the direction IV of Fig. 3; and

Fig. 5 shows schematically the use of the inclinometer

Alignment of a machine in the graphics industry. The first inclinometer 10 shown in FIGS. 1 and 2 has a contact body 12 made of metal with a rectangular outline and a longitudinally extending, bow-shaped profile that is symmetrical to the longitudinal center plane of the contact body 12. The bow legs 14 on both sides of the contact body 12 have flat lower contact surfaces 16 which meet in the longitudinal center plane of the profile and form an angle of approximately 165 ° with one another. The prismatic shape of the contact body 12 enables a stable support on the upper side of a cylinder 18, on both sides of the axis of which the stirrup legs 14 come to rest. Because of the large obtuse angle between the contact surfaces 16, the contact body 12 is suitable for resting on cylinders 18 of very different diameters.

The contact body 12 has at the apex of its contact surfaces 16 a rectangular groove 20 which extends in the longitudinal direction of the profile. The groove 20 is used for the simple production of the contact surfaces 16 by milling.

The stirrup legs 14 have parallel longitudinal side walls 22 and flat upper sides 24, which enclose an angle of approximately 120 °. The stirrup legs 14 thus thicken towards the center, where the contact body 12 has an upper, transversely oriented flattening. In this, a recess is provided in the center, which suitably accommodates a housing 26 for an electronic inclination sensor 30. The housing 26 is fixedly attached to the contact body 22 in a central position. It has a transverse bore 28 into which the cylinder body of the inclination sensor 30 is suitably inserted. The inclination sensor 30 measures the horizontal inclination of the profile axis and delivers a corresponding inclination angle signal. The second inclinometer 32 shown in FIGS. 3 and 4 has an approximately cuboid-shaped contact body 34 made of metal with narrow longitudinal sides 36, on the upper and lower ends of which projecting contact shoes 38 are formed. The contact shoes have flat rectangular contact surfaces 40 which lie in a common plane in front of the respective long side 36. The contact planes of the pairs of contact shoes 38 on both sides are parallel.

Magnetic holders are integrated into the contact shoes 38 and hold the inclinometer 32 to parts made of ferromagnetic material.

On the broad sides 68 of the contact body 34, large rectangular recesses 70 are provided at the top and bottom, which are opposite one another on both sides. The recesses 70 serve to reduce weight. A rib 72 remains between them, which ensures the required stability of the contact body 34.

On the top and bottom 42, 44 of the contact body 34 there is a centrally arranged, T-shaped handle 46 made of plastic.

The contact body 34 has a cylindrical transverse bore 48 in its central region. This accommodates the cylinder body of an electronic inclination sensor 50 in a suitable manner. The latter is firmly embedded in the contact body 34 in a central position. The inclination sensor 50 measures the vertical inclination of the contact planes 38 of the contact shoes 38 and supplies a corresponding inclination angle signal.

Apart from the central receiving area for the inclination sensor 50, the construction of the inclinometer 32 is mirror-symmetrical to all orthogonal center planes. FIG. 5 illustrates how a machine of the graphic industry is aligned according to the invention in a row construction when reinstalling or reinstalling. The machine component 52 newly installed at the front in each case has a base 54 which stands on four leveling feet 56 arranged at its corners. On the base 54, side stands 58 extend on both sides in the longitudinal direction, between which a number of transversely oriented cylinders 18 are mounted.

The machine component 52 is to be aligned so that the axes of the cylinders 18 are horizontal and mounting surfaces 60 on the front of the side stand 58 are oriented vertically. For this purpose, a first inclinometer 10 is placed on one of the cylinders 18 and a second inclinometer 32 with one of its pairs of contact shoes 38 is attached to the mounting surfaces 60.

The inclination angle signals of the inclination sensors 30, 50 are transmitted to a portable computer 64 (personal computer or laptop) via transceivers 62. This evaluates the signals for the alignment of the machine.

The invention is not restricted to the use of three inclinometers 10, 32. When aligning, a further inclinometer can be attached to a selected reference surface of the machine component 52, which remains accessible even after the next one has been attached. In particular, a first inclinometer 10 suitable for resting on the cylinder 18 should be considered here. Likewise, the inclination of the floor 66 on which the machine is standing can be detected with a further inclinometer. List of reference numbers

first inclinometer contact body stirrup leg contact surface cylinder groove longitudinal side wall top housing cross bore inclination sensor second inclinometer contact body long side contact shoe contact surface top underside handle cross bore inclination sensor machine component base leveling foot side stand mounting surface transceiver computer floor broadside recess rib

Claims

Expectations

1. Inclinometer for aligning machines in the graphics industry, in particular printing machines, with a contact body which can be applied to the machine, characterized in that the contact body (12, 34) is provided with an electronic inclination sensor (30, 50) and the inclinometer (10, 32) can be connected to an evaluation unit which processes an inclination measurement signal from the inclination sensor (30, 50).

2. Inclinometer according to claim 1, characterized in that the contact body (12, 34) is a solid metal body and is insulated against the heat of a hand holding the inclinometer (10, 32).

3. Inclinometer according to claim 1 or 2, characterized in that the contact body (12) has a profile with two inclined at an obtuse plane lower contact surfaces (16) and an inclination sensor (30) for the horizontal inclination of the profile axis.

4. Inclinometer according to claim 3, characterized in that the contact surfaces (16) enclose an angle of approximately 165 °.

5. Inclinometer according to claim 3 or 4, characterized in that the contact body (12) at the apex of the contact surfaces (16) has a groove (20) extending in the longitudinal direction of the profile.

6. Inclinometer according to claim 1 or 2, characterized in that the contact body (34) at least a pair of spaced-apart contact shoes (38) with flat contact surfaces (40) lying in a common plane, and an inclination sensor (50) for the vertical inclination this touch plane has.

7. inclinometer according to claim 6, characterized in that the contact body (34) on opposite sides (36) each has a pair of contact shoes (38), the contact planes are parallel.

8. Inclinometer according to claim 6 or 7, characterized in that the contact shoes (38) are magnetic holders.

9. Inclinometer according to one of claims 6 to 8, characterized in that a handle (46) is attached to the contact body (34) above and below the contact shoes (38) and in the middle between their contact planes.

10. Inclinometer according to one of claims 6 to 9, characterized in that the handles (46) consist of a material of low thermal conductivity, in particular plastic.

11. Inclination measuring system for aligning machines of the graphics industry, in particular printing machines, with at least one inclinometer (10) according to one of claims 3 to 5, with at least two inclinometers (32) according to one of claims 6 to 10 and with one

Evaluation unit to which the inclinometers can be connected at the same time and which processes their inclinometer signals simultaneously.

12. inclinometer or inclinometer according to one of claims 1 to 11, characterized in that the evaluation unit is a portable computer (64).

13. inclinometer or inclinometer according to one of claims 1 to 12, characterized in that a printer can be connected to the computer (64).

14. A method for aligning machines in the graphics industry, in particular printing machines, which have side stands, at least one cylinder mounted therebetween with a horizontally aligned axis and vertically aligned flat mounting surfaces on the front of the side stands and stand on leveling feet, characterized in that an inclinometer (10 ) according to one of claims 3 to 5 placed on the cylinder (18) and each an inclinometer (32) according to one of claims 6 to 10 fixed on the mounting surfaces (60), the inclinometers (10, 32) to an evaluation unit according to one of the Claims 11 to 13 connected and the printing machine is leveled on the basis of its simultaneous inclination measurement signal processing.

15. The method according to claim 14, characterized in that the inclinometer (10, 32) are initially calibrated by an envelope measurement.