DE102006008461B4 - Serrated measuring body - Google Patents

Abstract

Gear measuring body to Measuring gearing (7, 13), wherein the measuring body (1) at least partially made of a ferromagnetic material, characterized in that the ferromagnetic material (3) in the measuring body (1) is integrated, and that the ferromagnetic material (3) neither in the radial direction or in the axial direction over the measuring body (1), in particular a measuring surface of the measuring body (1) protrudes.

Description

Serve measuring body usually for measuring the tooth thickness directly or indirectly Gearing. In this case, tuned to the teeth measuring body in the tooth gap pressed.

The measuring body can but also used to measure the pitch deviation of racks become.

at all applications but must be guaranteed be that measuring body reliably abut against both tooth flanks of a tooth gap. Ideally lies the measuring body in the pitch circle of the teeth on the tooth flanks.

Around to ensure, that the measuring body to two tooth flanks of a tooth gap is applied, the measuring bodies are usually held by hand in contact with the tooth flanks. This means that to Measuring a gear at least one person is needed around the measuring body in the tooth gaps and a second person performs the actual measurement. at huge gears It may even be necessary for two people to place the measuring bodies in the tooth gaps hold. This means that for measuring the big gear a total of three people needed become.

From the US 4,319,400 an arrangement for determining the edges of a workpiece with a centering means is known, wherein this centering means 20 a magnet which is intended to hold the centering means in abutment with the workpiece.

From the US 2002/0129506 A1 a measuring body is known, which is firmly connected to one or more magnets. The Mageneten have the same diameter as the actual measuring body. A disadvantage of this measuring body is that they have a higher space requirement due to the externally arranged magnets and are more susceptible to incorrect measurements.

Of the Invention is based on the object, the measurement of gears or To simplify and facilitate racks and thus the susceptibility to errors to reduce the measurement.

These Task is inventively characterized solved, that the measuring body for measuring gears at least partially from a magnetized (ferromagnetic) or self-adhesive material.

ferromagnetic Room temperature properties show the elements iron, nickel and cobalt. Ferromagnetic materials have the property that between them and steel, especially hardened steel, as he used for gears is used, there is a magnetic attraction. These magnetic forces between measuring body and interlocking lead to that the measuring body Once it has been manually inserted into a tooth gap, it stays there. In addition, effect the magnetic forces, that the measuring body reliable in contact with the tooth flanks of the tooth gap remains.

People, which the measuring bodies hold are not required.

Thereby is the measurement of a gearing by a person with high reliability possible. These Person leads in a first step in the selected gullets each a measuring body and then measure the toothing, in particular the tooth thickness. Indirect is also the Measurement of tooth pitch possible.

there it is also possible insert the measuring bodies "over head" in a tooth gap, since suitable ferromagnetic materials are able to hold more than their own weight when in Attachment to a body made of steel, in this case a tooth flank of a toothing become.

With Help the measuring body according to the invention is it goes without saying also possible, the division of a rack, especially in the area of the impact between two racks to measure and adjust. Of course this can also be over your head take place, since the measuring body according to the invention her Can carry dead weight and as a result also in tooth gaps stay over that Head or are arranged at a different angle.

When ferromagnetic materials are especially iron, nickel and Cobalt or alloys containing at least one of these materials included, suitable.

which Material or which alloy in the concrete application of the Preference is given to a question arising from the magnetic properties, the cost of the material results and in an individual case by a specialist can be decided.

Especially It is advantageous if the measuring body is formed prismatic is, or if the measuring body has the shape of a cylinder.

A particularly advantageous because cost-effective and very durable Design of the measuring body according to the invention sees before that the measuring body having a core and a cladding, and that at least the core of the measuring body made of ferromagnetic material.

It is possible, commercial Magnets as a core for to use a measuring body according to the invention and the jacket of the measuring body Made of a suitable material and with the required precision. The jacket can be made of tool steel, for example and after hardening be ground, so first, it has a very high accuracy and at the same time is very resistant to wear.

Subsequently, will the core into a bore of the shell, acting as a through hole be executed can, used. The core may be, for example, by gluing or another joining process more or less firmly connected to the mantle. Of course it would be too possible, to introduce a blind hole in the mantle. It is also possible to use commercially available measuring rollers to magnetize.

Further Advantages and advantageous embodiments of the invention are the subsequent drawing, the description and the claims can be removed. All features described in the drawing, the description and the claims can be essential to the invention both individually and in any combination.

drawing

It demonstrate:

image 1 isometric illustrations of various embodiments of measuring bodies according to the invention,

image 2 shows a first example of application of the measuring bodies according to the invention,

image 3 shows a second application example of the measuring body according to the invention and the

images 4 to 6 measuring and adjusting the division of one of several Items of composite rack and pinion at the push of the racks.

Description of the embodiments

In Figure 1a is a first embodiment of a measuring body according to the invention 1 shown. This measuring body 1 consists of a core 3 and a cylindrical jacket 5 , The core 3 of the measuring body 1 consists of a ferromagnetic material, in particular iron, nickel and / or cobalt, and may be a commercially available permanent magnet. The core 3 is from a cylindrical shell 5 enclosed, whose material is the magnetic field of the core 3 not significantly affected.

The cylindrical outer surface (without reference numeral) of the shell 5 Can be machined by grinding, so that the cylindricity and the diameter of the measuring body 1 within close tolerances.

Of course it is also possible, the coat 5 made of another metallic material or a non-metallic material, such as ceramic or a high-strength plastic.

The core 3 can be glued into a longitudinal bore (without reference numeral) of the shell or by means of sealing plug at the ends of the longitudinal bore in the shell 5 be attached. It is advantageous if the core 3 free of play in the coat 5 is held.

To clarify the magnetic effect of the core 3 in Figure 1, the orientation or direction of magnetization is indicated by the letters N for north pole and S for south pole.

In the image 1b is a second embodiment of a measuring body according to the invention 1 shown. In this embodiment, the measuring bodies 1 completely made of ferromagnetic material. This naturally increases the magnetic force between the measuring body 1 and a gear, not shown. However, because of the required accuracy of the measuring body 1 , conventional commercial permanent magnets only after prior selection as inventive measuring body 1 use.

In As a rule, it will be necessary to make the cylindrical outer surface more commercially available To rework permanent magnets by a fine machining, so that the geometry and dimension of the measuring body in the required tolerance limits lie.

The embodiments according to Figures 1b) and 1c) differ only by the orientation of the magnetization. In the embodiment according to 1b) The separation plane between the north pole and the south pole runs in the direction of the longitudinal axis of the measuring body 1 while this separation level in the embodiment according to 1c) perpendicular to a non-illustrated longitudinal axis of the measuring body 1 runs.

Figure 2 is a first example of application of the measuring body according to the invention 1 shown. In picture 2 is a gear 7 shown in a side view. This gear 7 has, like every gear, several teeth 9 between those tooth gaps 11 are located. For clarity, not all teeth are 9 and all the teeth 11 of the gear 7 provided with reference numerals.

In two almost diametrically opposite tooth gaps (without reference numeral) of the gear 7 are two measuring bodies according to the invention 1 inserted. Because gears 7 Especially when it comes to highly loaded gears, made of steel, arises between the teeth of the gear 7 and the measuring bodies according to the invention 1 a magnetic force, which causes, first, the measuring body 1 always in contact with the tooth flanks (without reference numeral) of the teeth of the gear 7 and secondly, the measuring body arranged in Figure 2 below 1 against the gravity acting on it in the tooth gap 11 of the gear 7 held. It is therefore possible to use the magnetic measuring bodies according to the invention 1 after they have been put into the tooth gap, let go and thus has both hands free to perform the actual measurement. In the present embodiment, the measure A can be measured by a caliper, a micrometer or other measuring means (not shown) with great reliability and accuracy of only one person with the help of the measuring body according to the invention.

As the magnetic force between the measuring bodies according to the invention 1 and a steel gear is greater than the weight of the measuring body 1 , these can also be put over head.

Another field of application of magnetic measuring bodies according to the invention 1 is the measurement of pitch accuracy over a burst 15 in the continuous assembly of racks 13 , racks 13 are standard parts that are manufactured with high precision and are attached to the machine bed of the machine tool by the user, for example a manufacturer of machine tools. Because of course the length of the racks 13 limited, often need two or more racks 13 arranged one behind the other to achieve the desired overall length. This is a shock 15 between the adjoining racks 13 inevitable.

A first measuring body 1 is placed in a tooth gap, which arises where a rack 13 ends and the subsequently mounted rack 13 starts. In each case another measuring body 1 gets into a tooth gap of the ending and starting rack 13 placed. If a ruler is placed on these two rollers, this connecting line forms the basis for the graduation measurement. If all three measuring bodies 1 lie on this connecting line, so there is no graduation error at the shock 15 available (picture 4).

So that the accuracy of the teeth in the area of the impact is just as high as in the middle of the racks 13 It is necessary to have the adjacent racks 13 to align with each other. This is also possible over the head in a simple way with the aid of the magnetic measuring bodies according to the invention 1 possible.

Based on the pictures 4 to 6 is the setting of the shock 15 with the help of a measuring bridge 17 , a dial gauge 19 and three measuring bodies according to the invention 1 explained. The constellation shown in Figure 4 contains a base 21 the measuring bridge 17 and a measuring tip 23 the dial gauge 19 on a connecting line (not shown). The measuring tip 23 lies on a middle measuring body 1 up in the area of the push 15 between two adjacent racks 13 located.

The base 21 the measuring bridge 17 lies on measuring bodies 1 on, located in the right and left of the push 15 arranged tooth spaces are.

Before the actual measurement begins, the dial gauge must 19 For example, set on a granite plate so that the dial gauge shows "zero" when the probe tip 23 and the base 21 the measuring bridge 17 at one level (Figure 4).

If now the measuring bridge 17 with a dial gauge set in this way 19 on the three measuring bodies 1 can be read on the dial gauge, whether the tooth gap in the region of the shock 15 the same size, larger or smaller than the other tooth gaps of the racks 13 are.

In picture 4 is the push 15 set correctly, because the dial gauge 19 Indicates "zero". In contrast, in the picture 5, the shock 15 too small. As a result, the tooth gap in the area of the shock 15 narrower and the middle measuring body is pushed out of the tooth gap. That's why the measuring tip is located 23 no longer at the level of the base 21 the measuring bridge 17 , resulting in a corresponding modified display of the dial gauge 19 leads.

In picture 6 is the push 15 too big with the result that the middle measuring body 1 too deep in the tooth gap, in the area of the impact 15 lies, penetrates and consequently the measuring tip 23 not at the level of the base 21 the measuring bridge 17 is. As a result, the dial indicator also shows in this case 19 a nonzero value.

By moving the racks 13 to each other, the tooth gap in the region of the shock 15 can also be adjusted over head with great accuracy.

With magnetic or self-adhering measuring rollers (Figure 6) you can have a reliable Anla ge the measuring body 1 on the flanks of a gearing. It is irrelevant whether the measuring roller made of completely ferromagnetic material or a jacket 5 with a core 3 made of ferromagnetic material.

Claims (7)

Gear measuring body for measuring gears ( 7 . 13 ), wherein the measuring body ( 1 ) consists at least partially of a ferromagnetic material, characterized in that the ferromagnetic material ( 3 ) in the measuring body ( 1 ) and that the ferromagnetic material ( 3 ) neither in the radial nor in the axial direction over the measuring body ( 1 ), in particular a measuring surface of the measuring body ( 1 ) protrudes. Measuring body according to claim 1, characterized in that the measuring body ( 1 ) consists at least partially of iron, nickel and cobalt or an alloy of these materials. Measuring body according to claim 1 or 2, characterized in that the measuring body ( 1 ) is prismatic. Measuring body according to claim 1 or 2, characterized in that the measuring body ( 1 ) has the shape of a cylinder. Measuring body according to one of the preceding claims, characterized in that the measuring body ( 1 ) a core ( 3 ) and a coat ( 5 ), and that at least the core ( 3 ) of the measuring body ( 1 ) consists of ferromagnetic material. Measuring body according to claim 5, characterized in that the jacket ( 5 ) of the measuring body ( 1 ) made of steel, in particular hardened steel. Measuring body according to one of claims 5 or 6, characterized in that the jacket ( 5 ) of the measuring body ( 1 ) is ground.