SE522015C2 - Measuring device for e.g. thickness of object, has hydraulic braking arrangement for controlling speed at which measuring surfaces are moved together - Google Patents

Abstract

The measuring device includes two measuring surfaces (2, 8) which can be moved towards each other so that both surfaces are in contact with the object (3) being measured. A hydraulic braking arrangement (20, 24) is mechanically connected to the measuring arrangement (5) so that the hydraulic system reduces the speed at which the measuring surfaces are moved towards the object.

Description

25 30 35 52 2 01 5 ëffš - Ã fl fïf ”'2 In order to obtain a satisfactory measurement result, it is necessary, firstly, that the speed is not too high, since this leads to a strong impact on the object and thus a large impact on the measurement result, secondly that the speed is constant at each measurement, so that different measurement results are repeatable, reproducible and comparable.

SUMMARY OF THE INVENTION An object of the present invention is to solve the above problems, and to provide a measuring instrument which makes it possible to bring the measuring probe into contact with the object at a constant and reproducible speed.

A second object is to provide a measuring instrument without the need for an external power source.

These objects are achieved according to the invention with a measuring instrument of the kind initially indicated, which is provided with a brake arrangement, comprising a power device which is arranged to perform a movement against the action of a hydraulic system, the measuring arrangement being mechanically coupled to the brake arrangement so that an attack force coupled to said predetermined force is absorbed by the hydraulic system, so that the measuring surfaces of the measuring arrangement against the action of the hydraulic system at reduced speed are passable from the rest position to the measuring position, in which later position said predetermined force is absorbed by the object.

By means of the invention, the measuring surfaces can be moved towards each other at a constant and adjustable speed, which enables measurement of porous materials and ensures repeatability in the measurements.

In the brake arrangement, therefore, a pair of power acts consisting of the power of the power unit and the counterforce of the hydraulic system. This force pair can be several times greater than the smaller force pair which consists of the predetermined force which loads the measuring surfaces of the measuring arrangement, and its counter-force, which during the movement of the measuring arrangement comes from the hydraulic system. , and in the measurement mode comes from the object.

The mechanical coupling connects these two power pairs with each other, and the movement of the measuring surfaces towards each other is thus slowed down by the hydraulic system. When the measuring surfaces assume the measuring position, the coupling ceases, and the movement of the power unit continues to take place completely independent of the measuring arrangement.

Because the hydraulic system can be affected by a force that is several times greater than the force acting on the measuring surfaces of the measuring arrangement, a smooth and controlled movement can be ensured. The measuring surfaces can thus be brought into contact with the object at a constant and reproducible speed.

It should be noted that the predetermined force acting on the measuring surfaces, for example the part of the weight of a measuring probe which is not balanced by a counterweight, is normally so small that it could not bring about smooth movement against the action of a hydraulic system.

The hydraulic system suitably comprises a liquid-filled cylinder, and a piston movable in the cylinder, the piston dividing the cylinder into two chambers, which are connected to each other via a channel, and the liquid in the cylinder being movable from one chamber to the movement of the piston. Other. The hydraulic system is in this case a closed system, and is very easy to manufacture and maintain. Such a system also allows a simple control of the speed of movement of the power device, and thus the speed of the measuring surfaces towards the object, in that a control means such as a throttle valve is arranged along the channel, for regulating the flow speed in the channel.

The power device may be arranged to store potential energy, for example by comprising a spring which can be caused to apply a spring force to the hydraulic system, or a weight which is arranged to influence the hydraulic system by its weight. Such a power supply makes it possible to allow a user to supply the power of the power supply to each measuring device at each measuring time, whereby the need for an external power source is completely eliminated.

According to one embodiment, the measuring arrangement is arranged to, during the movement of the measuring surfaces from the rest position to the measuring position, make abutments against a portion of the brake arrangement whose movement is connected to the movement of the power device. When the measuring arrangement assumes the measuring position, this portion continues its movement and thus moves away from the measuring arrangement, whereby the attacking force, here in the form of an impact force, ceases.

Another possible variant is that the measuring arrangement via a flexible element, for example a tree, loads a part of the brake arrangement through the traction. When the meter arrangement assumes the measuring position, the part continues its movement and thus approaches the meter arrangement, whereby the attack force, here in the form of a traction force in the trees, ceases.

According to a preferred embodiment, the measuring arrangement is further arranged in a stand, which in the measuring position carries a substantial part of the weight of the measuring arrangement. In this way it is avoided that the weight of the measuring arrangement has a negative effect on the object in the measuring position. The measuring arrangement may, for example, comprise a balance rod, which at one end carries a measuring probe and at its other end carries a counterweight, and wherein said predetermined force consists of the part of the measuring probe's weight which is not balanced by the counterweight.

Brief Description of the Drawings The present invention will be described in more detail below with reference to the accompanying drawings, which for exemplary purposes show preferred embodiments of the invention.

Fig. 1 is a plan view of a thickness gauge according to an embodiment of the invention.

Fig. 2 is a perspective view of the thickness gauge of Fig. 1 in a first position.

Fig. 3 is a perspective view of the thickness gauge of Fig. 1 in a second position. 10 15 20 25 30 35 -. -. n.

Fig. 4 is a schematic diagram of the hydraulic system in the thickness gauge of Fig. 1.

Fig. 5 is a power diagram.

Description of a preferred embodiment The thickness gauge shown in Fig. 1 comprises a stand 1 which is fixedly connected to a base or a measuring table 2, on which a measuring object 3 can be placed. The stand 1 carries a measuring arrangement 5 which comprises a measuring probe 7, which is vertically movable in the direction of and away from the measuring table 2. The measuring probe is especially movable to a measuring position, in which it is in contact with a measuring object 3 on the measuring table 2.

The measuring probe 7 in the example shown comprises a measuring foot 8 located closest to the measuring table which is fixedly connected to an elongate portion 9. This elongate portion is movable in a device 10 of a kind known per se, comprising three rotatable rollers or wheels 11, between which the elongate portion 9 is movable.

The measuring probe is further connected to a measuring device 12 fixed in the stand, so that the vertical movement of the measuring probe is registered by the measuring device, for measuring the distance of the measuring foot 8 to the measuring table 2. In the example shown, the measuring device 12, which may be of the Mitutoyo brand , a shaft 41, which abuts an upper surface 42 of the portion 9. When the portion 9 is displaced upwards, the shaft 41 is pushed into the measuring device and a value corresponding to the displacement is shown on the display 43 of the measuring device.

The measuring arrangement shown further comprises a balance bar 14, which is pivotally arranged about a transverse axis 16 mounted on the frame. 9 fixed bracket 17 runs against the balance bar 14. At its other end, the balance bar 14 carries an adjustable counterweight 18.

The counterweight 18 is movable in the direction of the point of rotation of the balance bar 14, i.e. the transverse axis 15, and is in the .v-; x, ¿| a ||: o 10 15 20 25 30 35 522 015: -'s -: = .. =; : s sa s = -s-- "6 shown the example screwable along threads 19 in the rod 14. In this way the weight of the measuring probe 7 can be at least partially supported by the frame 1, whereby the weight of the measuring probe resting against the object in the measuring position is reduced. types of counterweight systems are conceivable, for example weights arranged in chains or belts, or pneumatic actuators.

The measuring instrument is further provided with a hydraulic system 20, comprising a cylinder 21 and a piston 22 which can be moved in the cylinder. hydraulic oil. The seals of the cylinders are suitably made of a material which allows low friction in the seals and which can withstand contact with oil, for example nitrile seals. The piston rod 23 of the piston is connected at its free end to a power device 24, which is movable against the action of the hydraulic system. In the example shown, the power device consists of a body 25 of a certain weight, which by the force of gravity acts against the piston.

In the hydraulic system 20 shown, as best seen in Fig. 4, the piston 22 divides the cylinder 21 into two chambers 21a, 21b, which communicate with each other through a channel 26 in the form of a hose or the like which is connected to openings 27a, 27b in the upper and lower part of the cylinder. The channel 26 is suitably in communicating connection with a buffer vessel 28. Along the channel 26, preferably at its connection to the opening 27b in the lower part of the cylinder, a control device 30 in the form of a throttle and non-return valve is arranged. The throttle 32 can be adjusted by means of an adjusting means 33, such as an adjusting screw (see Fig. 1).

An actuator 34 is provided adjacent the body 25, to allow a user to move the body to a higher position. The control lever comprises an elongate handle 35 (obscured in Fig. 1, but visible in Figs. 2-3), which is pivotable about an axis A at one end thereof.

From this point extends at an angle to the handle 35 a projection 36, which is arranged to make abutments against the body .. vu 10 15 20 25 30 35 5 2 2 015 The distance between the abutment of the projection with the body and the pivot point is preferably shorter than the distance between the pivot point and the gripping area of the handle, whereby a lever effect occurs and ensures a smooth and smooth movement.

The measuring arrangement 5 is further arranged to be coupled to the brake arrangement which consists of the hydraulic system 20, the power unit 24 and the operating device 34. In the example shown this is achieved by the body 25 and the hydraulic system 20 being located so that the balance rod 14 rests against the body 25.

The function of the measuring instrument will be described in the following.

A measurement (or series of measurements) is preceded by the need to reset the measuring device 12 in relation to the measuring table 2. The measuring instrument is then allowed to enter a rest position, where the measuring foot 8 strikes directly against the measuring table 2.

Then the measuring device 12 is reset, with a button 40 intended for this purpose.

The user first swings the handle 35 downwards, whereby the projection 36 swings upwards and lifts the body 25 to an upper position. Since the body 25 is connected to the piston 22 via the piston rod 23, this is also brought to an upper position. Furthermore, the balance rod 14 resting against the upper side of the body is caused to pivot, the measuring probe 7 translating vertically between the wheels 11 in the device. The measuring instrument is now in its "finished position", as shown in Fig. 2, and an object 3 whose thickness is to be measured can now be placed under the measuring foot 8.

The handle 35 is then moved upwards, whereby the projection 36 loses its contact with the underside 25a of the body 25.

The body 25 does not follow the movement of the projection 36 immediately, as it rests against the piston 21, which in turn moves against hydraulic action. The body 25 will therefore describe a very controlled movement, the speed of which is determined by the regulator 30. The balance bar 14 resting against the body 25 follows this downward movement, measuring 10 15 20 25 30 35 52 2 015 Éïï * ~ ~ 8 the probe 7 translates vertically downwards, in the direction of the measuring object 3.

The measuring probe 7 now assumes its measuring position, as shown in Fig. 3, in which the measuring foot 8 is in contact with the measuring object 3, whereby the movement of the measuring probe is hindered. The balance bar thus loses contact with the body 25, which continues its downward movement until the piston 22 reaches its bottom position in the cylinder 21. In the measuring position the measuring object 3 carries the part of the weight of the measuring probe which is not supported by the frame 1.

Fig. 5 shows a force diagram of the most important forces acting when using a measuring instrument according to the invention. The actuator applies a force F to the hydraulic system, whereby a counter force Fgwh arises, at the same time as the actuator moves in the direction of the force F. The measuring arrangement presses the measuring surfaces against each other with a predetermined loading force f ', which in the case shown is the force of gravity acting on the measuring probe 7 and which is not balanced by the counterweight 18. Before the measuring surfaces are brought into contact with the object, the measuring arrangement is braked by the load force f 'coupled force f is caused to act against the hydraulic system, whereby a counter force fm fl r arises. When the measuring arrangement assumes the measuring position, f 'is instead occupied directly by a counter-force f'dÜ from the object 3, whereby the force pair f, fm fi r ceases to operate. In the example shown, the force f arises where the balance bar 14 rests against the body 25, and since this point is closer to the axis of rotation of the balance bar, f is greater than f '. This is of course not necessary, and through a different placement the relationship could have been the other way around. The forces f 'and f also do not have to be parallel.

The measuring probe 7 can of course be oriented differently than in the embodiment described above, and for example be horizontally movable. This can be beneficial in certain types of measurements. The measuring probe can also be inverted, ie the measurement can be performed during the upward movement n na-a ~ o 10 15 20 o .v u. 522 01 5 Éïï * z 9 se, by a simple reconstruction of the measuring instrument for the person skilled in the art.

The measuring instrument in the above description is intended for thickness measurement, but at least in the following applications it is also advantageous to use a measuring instrument according to the invention: 0 surface roughness measurement (Bendtsen) A measuring probe is lowered towards the sample, air is pressed into the measuring probe and the leakage between the measuring probe and the material shows the surface roughness of the material.

In rewetting Absorbent filter paper is placed on a moistened sample, after which a specified weight is applied to the filter paper so that liquid is forced up from the sample and absorbed by the filter paper. 0 moisture content measurement A measuring probe is lowered towards the sample to measure the moisture content. 0 deformation measurement A weight is lowered towards the sample for measuring deformation over time.

Claims (13)

10 15 20 25 30 35 522 015 u e | ø u au 10 PATENT REQUIREMENTS Measuring instrument for measuring properties of an object, comprising a measuring arrangement (5) with two relatively movable measuring surfaces (2, 8), which under the action of a predetermined force (f ') are passable from a rest position, in which the object (3) is insertable between the measuring surfaces, to a measuring position, in which both measuring surfaces are in contact with the object, characterized by a braking arrangement (20, 24), to apply a compressive force (F) comprising a power device (24) arranged against a hydraulic system (20), and perform a smooth and controlled movement against the action of the hydraulic system (20), the measuring arrangement (5) being mechanically coupled to the braking arrangement (20, 24) by applying a predetermined force to said (f ') coupled attack force (f) is absorbed by the hydraulic system (20), so that the measuring surfaces (2, 8) of the measuring arrangement against the action of the hydraulic system (20) at reduced speed can be moved from the rest position to the measuring position, in which later ( f ') (3) and said attack pskraft (f) ceases. position said predetermined force is occupied by the object Measuring arrangement according to claim 1, wherein said pressure force (F) is several times greater than said predetermined force (f '). Measuring instrument according to claim 1 or 2, wherein the hydraulic system (20) comprises a liquid-filled cylinder (21), and a piston (22) which can be moved in the cylinder. Measuring instrument according to claim 3, wherein the piston (22) divides the cylinder (21) into two chambers (2la, 2lb), which are connected to each other via a channel (26), and wherein the movement of the piston is movable 2lb) to the second (21b, the liquid in the cylinder (21) from one chamber (2la, 2la). Measuring instrument according to claim 4, wherein a control (30) for regulating means is arranged along the channel (26), 10 n 20 n 25 n n n n n n n n n n. n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n. A measuring instrument according to claim 5, wherein the control means comprises a throttle valve (32). Measuring instrument according to one of the preceding claims, wherein the power device (24) is arranged to store potential energy. Measuring instrument according to claim 7, wherein the power device (24) comprises a spring. Measuring instrument according to claim 7, wherein the power device (24) comprises a body (25) which is arranged to influence the hydraulic system (20) by its weight. Measuring instrument according to one of the preceding claims, wherein the measuring arrangement (5) is arranged to make an (20, 24) (24) movement during the movement of the measuring surfaces from the rest position to the measuring position. impact on a portion of the brake arrangement whose movement is connected to that of the power tool Wherein the measuring arrangement Measuring instrument according to any one of the preceding claims, (5) which in the measuring position carries a substantial part of measuring arrangement - is arranged in a weight (1), ets (5) weight. Measuring instrument according to claim 11, wherein the measuring arrangement (5) comprises a balance rod (14), which carries at its one end a measuring probe (7) and at its other end up (19), (f ') is constituted by the part of the weight of the measuring probe which does not carry a counterweight and wherein said predetermined force is balanced by the counterweight. Use of a measuring instrument according to any one of the preceding claims, for measuring the thickness of an object (3) of a porous material.