SE510793C2 - Device for measuring inner dimensions of cylinder lining - Google Patents

Abstract

The invention concerns a device for determining the internal measurements of a cylinder lining (6). Primarily large-size cylinder linings (6) are concerned, such as those used in marine engines. The device comprises a suspension unit (4) which is arranged to be placed above an essentially vertically upright cylinder lining (6). The device further comprises a measuring unit (5) which is arranged to be lowered from the suspension unit (4) into the cylinder lining (6) and which is provided with means (28, 34, 36) for performing a series of measuring operations and determining distances from a line of reference (11) extending between the suspension unit (4) and the measuring unit (5) to the inner wall (26) of the cylinder lining (6) at a plurality of levels and in several different radial directions at each level.

Description

510 793 2 10 15 20 25 30 35 and the size of these. However, the method is completely insufficient to assess the possible deviations of the cylinder liner from the cylinder shape, ie whether the cylinder liner has been deformed to an S-shape by thermal stresses or has become slightly curved like a web.

The invention has provided a device which makes it possible, after disassembly of only a few engine parts, to quickly and relatively easily make a larger series of measurements in an arbitrary number of radial directions at a certain level from a cylinder liner towards its inner wall and at an arbitrary number levels in the cylinder liner. What is characteristic of this device is stated in the appended claims.

Several possible embodiments of the invention will be described in more detail below with reference to the accompanying drawings, in which Fig. 1 shows in broken view a cylinder equipped with the device according to the invention, consisting of a suspension unit, resting on top of Fig. 2 shows an exploded perspective view of details. which is included in the cylinder and a measuring device immersed in it, the suspension unit, Fig. 3 also shows in perspective an exploded view of parts which are included in the measuring unit, and Figs. 4 and 5 show alternative embodiments of the measuring unit.

Fig. 1 shows a cylinder 1 with a piston 2 and a top 3, from which an exhaust valve has been removed to make room for the measuring device according to the invention. This consists of a suspension unit 4, which is intended to rest on the cylinder head 3, and a measuring unit 5, which is submersible in the cylinder 1. A liner 6 is inserted therein, on which measurements are to be made.

The suspension unit 4 is connected to the measuring unit 5 via ropes or, as shown in the drawing, belt 7. Each belt 7 is unrollable from or rollable on a roller 8, which is driven by a motor 9. Control means not shown in the drawing are arranged to control each motor 9 operation, so that in each position you have control over the rolled-out band length and thus at what level the measuring unit 5 is. 510 7931 The suspension unit 4 is provided with a laser directing means 10, which directs a light beam 11 down to a (PSD) directing means 10 is suitably arranged in the manner as a position-sensitive detector 12 in the measuring unit 5. Laser better is shown in Fig. 2. A translation table consists of two plates 13,14, which by means of their respective adjusting nuts 15 and 16 are displaceable at a 90 ° angle relative to each other. The plates 13, 14 are provided with their respective oval holes 17 and 18, respectively, which are located at right angles relative to each other. The laser directing means 10 is arranged in a bushing 19, which in turn is arranged in the two oval holes 17, 18. The laser directing means 10 is further provided with a curved portion 20, which is intended to engage in a bulge 21 in the bushing 19.

By means of the described parts belonging to the translation table, the laser directing means 10 can be displaced laterally in two mutually perpendicular directions and also regulate its inclination, so that the light beam 11, which is intended to form a reference line for setting the measuring unit 5, strikes the PSD. 12 as close to its center as possible.

In the embodiment shown in Figs. 1 and 3, the upper unit 5 comprises an upper ring 22. From this extends radially outwards three actuators 23 and from these in turn three frame legs 24, each of which at its free end is provided with a pulley 25, which by means of respective actuators 23 can be attached to the inner wall 26 of the cylinder liner 6. The actuators 23 can consist of linear devices with integrated motor of known design and be used to center the measuring unit 5 in the cylinder liner 6, before measurements begin.

After lowering the measuring unit 5 to the desired level and placing the pulleys 25 against the inner wall 26, the upper ring 22 is non-rotatably clamped in the cylinder liner 6.

The measuring unit 5 further comprises a lower ring 27, through which a measuring rod 28 extends. The lower ring 27 is fixedly connected to a drive ring 29, which in turn is connected to the upper ring 22 via a bearing 30. The drive ring 510 793 The ring 29 and thus the lower ring 27 and the measuring rod 28 are rotatable all the way around in one or the other direction by means of a stepper motor 31, which is connected to the drive ring 29 via a toothed belt 32, as shown in Fig. 3. , or otherwise.

The measuring rod 28 is mounted in the lower ring 27, for example in ball bushings (not shown), and is displaceable radially for abutment against the inner wall 26 of the cylinder liner 6 by means of a solenoid 33. The PSD 12 is arranged on the measuring rod 28 in the center of the measuring unit 5.

Fig. 4 shows an alternative to the embodiment of the measuring unit 5. According to this alternative, instead of the measuring rod 28, the measuring unit 28 is provided with a substantially horizontally arranged laser directing means 34. On its upper side, the PSD 12 is arranged for aligning this measuring unit 5 'in the same way as previously described by means of the light beam 11. The laser directing means 34 is arranged to direct a second light beam 35 towards the inner wall 26 of the cylinder liner 6. The laser directing means 34 is rotatable 360 ° for determining an arbitrary number of radius dimensions.

Fig. 5 shows another alternative for carrying out the measuring unit. In this case the measuring unit 5 "is provided with a vertically arranged laser directing means 36, which towards an inclined, rotatable mirror 38 directs a light beam 37, which is deflected perpendicular to the inner wall 26 of the cylinder liner 6. By rotating the mirror 38 one can thus determine radius dimensions at different angles. The PSD 12 for aligning the measuring unit 5 ”in the middle of the cylinder liner 6 is in this case placed on the upper end side of the laser directing means 36.

The device according to the invention also includes a stand-alone computer unit (not shown in the drawing), in which a program for measuring a cylinder liner 6 can be entered. A software module (processor) on the suspension unit is also connected to this computer unit. 4 and one on the measuring unit 5. The values to be registered are, in addition to radius measurements, also the temperature of the cylinder liner 6 at each measuring point and the time and date.

Before starting a measuring procedure, the position of the laser aiming member 10 is checked and possibly adjusted in order to make its light beam 11 serving as a reference line coincide as well as with the longitudinal axis line of the cylinder liner 6. Thereafter, the measuring unit 5 is lowered to a lowest position and its centering and inclination in the cylinder liner 6 is measured and corrected, after which the upper ring 22 is fixed.

A pre-programmed measuring process can now start, whereby the measuring unit 5 performs a series of radius measurements with the lower ring 27 or the laser directing means 34 or the mirror 38 set at different angles of rotation. Measured values are stored in the processor memory of the measuring unit 5 and are then transferred either to the processor memory of the suspension unit 4 or directly to the computer unit. After detaching the measuring unit 5, raising it one step and fixing at the higher level, the described measuring process is repeated. As soon as a complete measurement procedure has been performed and all measurement values have been stored, for example, in the suspension unit 4's processor memory, the values can be transferred to the computer unit for presentation and analysis. that the computer unit on a screen shows total radius measurements in a Presentation of the measured values can take place in this way, diagrams with height curves and entered numerical data similar to a topographic map. You can also make the presentation in the form of a color pattern with a simultaneous indication of which depth or height measure each color corresponds to.

The device according to the invention is very simple and practical to work with. As mentioned above, the measuring unit 5 is fixed before starting a measuring process by means of the actuators 23. By measuring the position of the light beam 11 in the x- and y-directions on the PSD 12, see Fig. 1, in this position calculate a normalized radius measure, which is stored in the processor of the suspension unit 4. The light beam 11 then serves as a reference line, by means of which it can be determined during the measurement process in addition to the determination of radius dimensions whether the cylinder liner 6 is, for example, curved (banana shape) or otherwise deviates from exact cylinder shape.

In order to further simplify or accelerate the evaluation of the measuring process, one can choose to show only such parts of the inner path 26 of the cylinder liner 6, where the radius measurements deviate from a certain limit value within a limited area. In this way, one can get a quick idea of unacceptable local wear on the cylinder liner 6.

An advantage is if the processor of the suspension unit 4 is so powerful that an entire measuring process can be stored in it and thus no external control is required.

Namely, in such a case it is not necessary to take a computer unit out for a measurement in a machine room, but collected measurement data can instead be transferred to the computer unit and presented elsewhere. This also does not impose any requirements for fast transmission of measurement data to the computer unit in real time.

The invention is not limited to what has been shown and described but can be varied in a number of ways within the scope of the appended claims. Thus, for example, on the suspension unit 4, one can have a laser distance meter, which directs a light beam towards a reflecting surface on the measuring unit 5. Furthermore, instead of, as shown in Fig. 2, the laser aiming means 10 can be arranged with a curved portion 20 in the entire translation table. a cradle.

Claims (10)

10 15 20 25 30 35 510 793 7 PATENT REQUIREMENTS Device for measuring the internal dimensions of cylinder liners, preferably larger cylinder liners, such as for ship engines, characterized in that the device includes a suspension unit (4), which is arranged to be mounted above a substantially vertically upright cylinder liner (6). ) and resting on the cylinder tip (3) in question, and a measuring unit (5) submersible in this cylinder unit (4) in the cylinder liner (6), which is provided with means (28,34,36) for performing a series of measurements and determining distances. from a reference line (11) extending between the suspension unit (4) and the measuring unit (5) and the inner wall (26) of the cylinder liner (6) on several levels and in several radial directions on each level. Device according to claim 1, characterized in that the measuring unit (5) is suspended in ropes or bands (7), which can be wound on or unwound from rollers (8) on the suspension unit (4) for adjusting the measuring unit. (5) height adjustment. Device according to one of the preceding claims, characterized in that the suspension unit (4) is provided with a first laser directing means (10), which is arranged to direct a light beam (11) towards a unit located at the measuring unit (5). position-sensitive detector (12), which light beam (11) constitutes said reference line. Device according to one of the preceding claims, characterized in that the first laser directing means (10) (13, 14), in which the laser directing means (10) is movable substantially perpendicular to the direction of the light beam (11) in two arranged in a translation table mutually perpendicular directions, which translation table consists of a lower plate (14) with an oval hole (18) and an upper plate (13) with a similarly oval hole (17) extending perpendicular to the first-mentioned hole ( 18) in a plane located above and parallel to the plane this hole (18) is located in, and that the laser directing means (10) extends through the two holes (17, 18). Device according to claim 4, characterized in that the first laser aiming means (10) is (20), which is approached, provided with a bushing (19) (21) (21) (21) (arranged around a circumferential arched portion). 19), to enable adjustment of the laser directing means (10) in different positions in one of the holes in a corresponding bulge in the bushing inclination positions. k ä n n e t e c k - that the measuring unit (5) Device according to claim 1, furthermore, is provided with at least three radially in each direction from the measuring unit (24), actuators (23) are extendable into contact with the unit (5) of the cylinder liner (6) at a certain intended level in the cylinder liner (6). (5) projecting frame legs which by means of their inner wall (26) for the purpose of anchoring the measuring Device according to claims 1 and 6, characterized in that the measuring unit (5) is provided with a part (27) rotatable relative to the frame legs (24) and that (27) is provided with the means (28, 34, 36) for measuring the distance to the inner wall (26) of the cylinder liner (6). Device according to claims 3 and 7, characterized in that this part is drawn therefrom, (24) (34), which is provided on its upper side with a position that said member is constituted by a rotatable relative to the frame legs, second laser direction means sensitive detector (12), which is arranged to capture the reference line constituting the light beam (11) from the (10) position, the first laser direction means and determining the second (34) (34) light beam (35) substantially perpendicular to the first laser direction means and the second laser directing means is arranged to emit a second light beam (11) in the direction of a certain point on (26) the distance between the reference line constituting the light beam the inner wall of the cylinder liner (6) for determining (11) and said point on the inner wall (26) . Device according to claim 8, characterized in that the second laser directing means (36) is (24) a downwardly directed light beam (37) and that a rotatable mirror arranged stationary relative to the frame legs with (38) is arranged to catch this light beam (37) and direct it towards the inner wall (26) of the cylinder liner (6) substantially perpendicular to the light beam (ll) constituting the reference line. k ä n n e t e c k - (27) adjustable in different rotational positions by means of a stepper motor (31) Device according to claim 7, characterized in that the rotatable part is included and that it comprises a measuring rod (28), which is provided with a position-sensitive detector (12), which is arranged in the beam path of the reference line constituting ( ll) and which is displaceable in its longitudinal direction to (26) determining the distance between the reference line out- (ll) and the currently valid contact point on the inner wall (26). the light beam and arranged to determine the contact of the measuring rod (28) with the position of the cylinder liner (6), inner wall of the making light beam