DE19546076A1 - Foldable meter rule for linear measurement with multiple set length rigid members - Google Patents

Abstract

The meter rule has a one measurement scale on the front side and a second scale at the rear side. The first scale is so arranged, on the front side, that the measuring numbers run from one end to a second end, with rising numbers from minimum to maximum value. The individual members of the linear measuring system (20) are connected with each other at the pivot joints (23) so that, with the observation of the front side, the member with higher scale values continuously lies under the adjacent member with the lower measuring values. The second measurement scale on the rear side is so arranged, that the measuring numbers from one end of the measuring system to its second end, have increasing number values from minimum to maximum measurement values. The members of the set length are connected in pairs, so that they can be folded up to different lengths.

Description

The invention relates to a collapsible measuring device a scale (hereinafter referred to as the yardstick) and in particular the arrangement of the measuring scale on this Measuring device.

In FIGS. 9 to 11, an example of a known meter stick with a length of 2 m is shown.

As FIGS. 9a and 9b show, such a meter rod 1 usually consists of a plurality of rigid links 4 a - 4 j with a predetermined length (in the example given ten links each 20 cm), which at their ends are connected via a swivel 3 a - 3 i are connected in pairs so that the rod can be opened to different lengths.

A scale 2 is usually formed on both the front and the back of the yardstick 1 . The scale 2 is arranged on the front so that the dimensions run from the left end of the meter rod 1 a to the right end of the meter rod 1 b with an increasing numerical value from the minimum to the maximum measured value (see Fig. 10a). If you turn the yardstick half a turn around the longitudinal axis 1 a- 1 b, you look at the back of the yardstick 1 , as shown in Fig. 10b. On this page, the scale 2 is formed so that the dimensions run from the right end of the meter rod 1 b to the left end of the meter rod 1 a with increasing numerical values from the minimum to the maximum measured value, these numbers being upside down when looking in accordance with Fig. 10b.

The individual yardstick members 4 a - 4 j are connected to one another at the swivel joints 3 a - 3 i so that a member with higher scale values is always below the neighboring member with the lower measured values. For example, (Fig. 9b and 10a) is the member 4b in the direction of view of FIG. 10 under the member 4 a, because on the front of the member 4 b larger numerical values than on the front side of the member 4a. Link 4 a shows the numbers 0-20, link 4 b shows the numbers 20-40. When looking at the back of the meter stick 1 according to FIG. 10b, the same applies analogously. The scale 2 running in the opposite direction now leads to the fact that the element 4 j displays lower measured values than the element 4 i. Link 4 j shows the numbers 0-20, link 4 i shows the numbers 20-40. The link 4 i is therefore below the link 4 j in the viewing direction according to FIG. 10b.

The described arrangement of the scale, it is in the collapsed state of the meter rod 1 (Fig. 9b) for the user no matter whether he unfolds the meter rule beginning with the member 4 a or the member 4 j. The yardstick 1 is completely symmetrical in this respect, the views of the links 4 a and 4 j are identical in the folded state.

This symmetry, which at first glance appears to be advantageous, has a decisive disadvantage, which is described below. FIGS. 11a-11c show the meter stick 1 in a partially unfolded state, which releases c at a front view of the three members 4 a to 4 (Fig. 11a). Under the link 4 c there are the remaining, folded links 4 d- 4 j ( Fig. 11b). As the rear view according to FIG. 11c shows, the scale on the back runs from the end of the meter rod 1 a starting from the maximum measured value to smaller numbers.

In Fig. 12a it is shown how a short distance 6 must be measured, which is located between two delimiting walls 5 a, 5 b. The walls 5 a, 5 b prevent the yardstick 1 from being fully opened. The folded part of the yardstick 1 makes it impossible to lay the links necessary for the measuring process flat on the distance to be measured. This means that the measuring process is either very inaccurate, or the meter rod 1 must be bent by the user, which leads to an increased risk of breakage, especially with wooden meter rods. Even angling the meter rod 1 to the side ( FIG. 12b) does not solve this problem (if the surroundings of the section 6 to be measured permit such an angling at all). The profit is at most one member of the yardstick 1 . A lateral placement of the meter stick 1 is only possible if the measuring section 6 can be viewed from the side. That is e.g. B. impossible for all box-shaped objects.

Placing the folded part of the yardstick 1 upwards, as shown in FIGS. 4a and 4b, leads to another difficulty in the known yardsticks. In this case, the user sees the scale of the yardstick 1 as shown in Fig. 11c. The scale runs backwards from the largest possible measured value (200 cm for the given example) to smaller scale values. To determine the actual length of the measuring section 6 , the user must therefore make the following difference:

actual length = max. Scale value minus measured value

This means that the user must always take the measured value of the maximum Subtract the scale value. This calculation process leads because of Four-digit numbers used (measuring range in the specified Example equal to 2000 mm) often on site (construction site) Volatility errors.

Another disadvantage that always occurs when the distance to be measured 6 is less than the length of a yardstick 4 _n (n = a... J) from the left boundary wall 5 a is that the values of the scale 2 for the user upside down. This leads to further reading errors.

The object of the invention is therefore a collapsible To create measuring device with a scale, which is also in the Measuring short distances in confined spaces is easy and can be read without errors.

A collapsible measuring device according to the invention has a plurality of rigid links with a predetermined length, the  their ends are connected in pairs so that the measuring device opened to different lengths a first scale on the front and one second scale on the back. The first scale is arranged on the front so that the dimensions of one first end of the measuring device to the second end of the Measuring device with increasing numerical value from minimum to run to the maximum measured value. The individual links of the Length measuring device according to the invention are on the rotary joints connected so that when looking at the front a link with higher scale values always below the neighboring one Link with the lower measured values.

In a preferred embodiment, the second scale is on the back arranged so that the measures from the first end the measuring device to the second end of the measuring device ascending numerical value from the minimum to the maximum measured value to run.

In a further embodiment, the second scale is on the back arranged so that the measures from the first end the measuring device to a predetermined location on the Measuring device with increasing numerical value from minimum to run to the intermediate value on the second scale of the corresponds to the predetermined position. There is also a third scale formed on the back so that the dimensions from the second End of the measuring device up to the predetermined position on the Measuring device with increasing numerical value from minimum to run to the intermediate value on the third scale of the corresponds to the predetermined position. The top-bottom orientation of the Numbers on the third scale are preferred equal to the top-bottom orientation of the numbers on the second Scale.

It is also possible that the second and third measuring scales partially or completely overlap, d. that is, it is not common endpoint formed.

A collapsible measuring device according to the invention has a plurality of rigid links with a predetermined length, the  their ends are connected in pairs so that the measuring device opened to different lengths a first scale on the front and one second scale on the back. The first scale is arranged on the front so that the dimensions of one first end of the measuring device to the second end of the Measuring device with increasing numerical value from minimum to run to the maximum measured value. The second scale is on the Rear arranged so that the dimensions from the second end of the Measuring device with the first end of the measuring device ascending numerical value from the minimum to the maximum measured value to run. The individual links of the invention Length measuring devices are so together at the swivel joints connected that a link with higher scale values always above that neighboring link with the lower measured values.

The inventive formation of the measuring scales on the Yardstick can also cover short distances under cramped conditions Ratios can be measured easily and without errors because of the folded part of the yardstick when using the second measuring scale is located above the scale to be read. On Bending the yardstick to improve measurement accuracy is not necessary. On site, therefore, is both error-free Handling ensures as well as a risk of breakage improper handling avoided.

Further features and practicalities result from the Description of exemplary embodiments with reference to the figures. From the figures show:

Fig. 1a, 1b a first embodiment of the yardstick according to the invention in the folded state in a front view and side view;

Figures 2a, 2b of the meter stick according to the invention of Figure 1 in the fully unfolded state in a front view and a rear view..;

FIGS. 3a-3c of the meter stick according to the invention of Figure 1 in a partially unfolded state in a front view, a side view and a rear view.

. Fig. 4a of the meter stick according to the invention of Figure 1 in a partially unfolded state when measuring a short distance;

Fig 4b of the meter stick according to the invention of Figure 1 in an angled state when measuring a short distance..;

Figures 5a, 5b, a second embodiment of the erfindungsgeinäßen meter rule in the folded state in a front view and a rear view.

FIG. 6a, 6b, a third embodiment of the meter rod according to the invention in the folded state in a front view and side view;

Figures 7a, 7b of the meter stick according to the invention of Figure 6 in the fully unfolded state in a front view and a rear view..;

Figures 8a-8c of the meter stick according to the invention of Figure 6 in a partially unfolded state in a front view, a side view and a rear view..;

Figs. 9a, 9b is an example of a known meter rule in the folded state in a front view and a rear view;

FIG. 10a, 10b of the measuring stick according to Figure 9 in the fully unfolded state in a front view and a rear view.

FIG. 11a-11c of the meter stick of Figure 9 in a partially unfolded state in a front view, a side view and a rear view.

FIG. 12a the meter stick according to FIG. 9 in a partially opened state when measuring a short distance; and

Fig. 12b the yardstick according to Fig. 9 in an angled state when measuring a short distance.

Figs. 1-3 show a first embodiment of an inventive meter rod having ten members per cm to 20 and therefore a total length of 2 m has. As shown in FIGS. 1a and 1b show, there is a meter rod 10 from a plurality of rigid members 14 a-14 j with a length of 20 cm, the a- at their ends via a swivel joint 13 are 13 i connected in pairs so that the Rod can be opened to different lengths. The individual meter bar members 14 a-14 j are connected at the pivots 13 a-13 i to each other so that always lies in viewing the front side 12 a member having a higher scale values below the adjacent link with the lower measurement values. For example, in the direction of view according to FIG. 1a, the link 14 b with the dimensions 20-40 is below the link 14 a with the dimensions 0-20.

As shown in Fig. 2a, a first scale 12 a is formed on the front of the yardstick 10 so that the dimensions run from the first meter end 11 a to the second meter end 11 b with increasing numerical value from the minimum to the maximum measured value. As shown in FIG. 2b, a second scale 12 b is formed on the back of the meter rod 10 so that the dimensions run from the first meter rod end 11 a to the second meter rod end 11 b with an increasing numerical value from the minimum to the maximum measured value. Contrary to the known yardstick (see FIG. 10b), these numbers are not upside down when looking in accordance with FIG. 2b.

FIGS. 3a-3c show the meter rod 10 in a partially unfolded state similarly as in FIGS. 11a-11c in a front view of the three members 14 a to 14 c to the first graduated scale 12 a release (Fig. 3a ). Under the link 14 c there are the remaining, folded links 14 d- 14 j ( Fig. 3b). As the rear view according to FIG. 3c shows, the second measuring scale 12 b on the back of the first meter rod end 11 a in the meter stick according to the invention now differs from the known meter stick with the value 0 and runs to larger numbers. This makes it easy to read the scale in this state.

Fig. 4a shows the use of the yardstick 10 according to the invention when a short distance 16 must be measured, which is located between two delimiting walls 15 a, 15 b. The walls 15 a, 15 b also prevent the yardstick 10 from being fully opened. However, in contrast to the known yardstick, this is not a problem because the yardstick 10 can be placed flat on the distance 16 to be measured, that is to say with the links 14-14 j folded up. The user sees in this case the second graduated scale 12 b as shown in Fig.'S 3c. It is immediately apparent that the reading of the scale 12 b can be done without any problems and errors. A conversion of the read value into an actual length value, as is necessary with the known yardstick, is not necessary. In addition, the yardstick 10 does not have to be bent in the case according to FIG. 12a in order to increase the measuring accuracy. Therefore there is no risk of breakage. The same applies to a lateral angling of the yardstick 10 ( Fig. 4b).

If the user wishes to measure a distance from right to left, ie in Figs. 4a and 4b, starting from the wall 15 b or a location in the vicinity of the wall, so must the first end 11 applied 15 b a of the meter bar 10 at the starting point . As a result, the second measuring scale 12 b to be read is upside down for the user.

FIGS. 5a and 5b show a second embodiment of an inventive meter rule similar to the first embodiment, ie, the meter rod 10 has ten members, each of 20 cm and therefore has a total length of 2 m. Fig. 5a shows the meter rod 10 in the second embodiment in a front view, Fig. 5b, in a rear view. The difference to the first embodiment ( Fig. 1-3) consists in the formation of a third measuring scale 12 c. Again, the individual meter bar members 14 a-14 j to the rotary joints 13 a-13 i connected with each other so that always lies in viewing the front side 12 a member having a higher scale values below the adjacent link with the lower measurement values. For example, in the direction of view according to FIG. 5 a, the link 14 b with the dimensions 20-40 is located below the link 14 a with the dimensions 0-20.

As shown in Fig. 5a, a first scale 12 a is formed on the front of the yardstick 10 as in the first embodiment. As Fig. 5b shows, on the back of the meter stick 10, a second scale 12 b is formed so that the dimensions run from the first meter stick end 11 a to an intermediate point (not shown) on the meter stick 10 with an increasing numerical value from the minimum to the measured value , which corresponds to the intermediate point on the second measuring scale 12 b. Furthermore, a third scale 12 c is formed on the back of the meter rod 10 so that the dimensions from the second meter rod end 11 b to the (not shown) intermediate point on the meter rod 10 with increasing numerical value from the minimum to the measured value that the intermediate point on the corresponds to third measuring scale 12 c. The numbers of the second and third measurement scale 12 b, 12 c have in the direction of view of FIG. 5b same Up-Down orientation.

In a further embodiment, it is possible for the two scales 12 b and 12 c to overlap partially or completely on the back of the yardstick 10 . In the latter case, the scales 12 b and 12 c each run over the entire length of the yardstick 10 . The second measuring scale 12 b is then formed such that the dimensions run from the first meter rod end 11 a to the second meter rod end 11 b with an increasing numerical value from the minimum to the maximum measured value. The third measuring scale 12 c is formed so that the dimensions run from the second meter rod end 11 b to the first meter rod end 11 a with an increasing numerical value from the minimum to the maximum measured value. Also in this case, the numbers of the second and third measurement scale 12 b, 12 c in the direction of view of FIG. 5b the same top-bottom orientation.

Figs. 6-8 show a third embodiment of an inventive meter rod having ten members per cm to 20 and therefore a total length of 2 m has.

As shown in FIGS. 6a and 6b show, there is a meter rod 20 from a plurality of rigid members 24 a-24 j with a length of 20 cm, the a- at their ends via a swivel joint 23 are 23 i connected in pairs so that the Rod can be opened to different lengths. The individual meter bar members 24 a-24 j are connected at the pivots 23 a-23 i to each other so that always lies in viewing the front side 22 a member having a higher scale values to the adjacent member with the lower measurement values. Recordable manner is located in the direction of view of FIG. 6a, the member 24 b with the metrics 160-180 under the member 14 a with the metrics 200-180.

As shown in Fig. 7a, a first scale 22 a is formed on the front of the yardstick 20 so that the dimensions run from the first meter end 21 a to the second meter end 21 b with increasing numerical value from the minimum to the maximum measured value. As shown in FIG. 7b, a second scale 22 b is formed on the back of the meter rod 20 so that the dimensions run from the second meter rod end 21 b to the first meter rod end 21 a with an increasing numerical value from the minimum to the maximum measured value.

Figs. 8a-8c show the meter rod 20 in a partially unfolded state similarly as in FIGS. 11a-11c, the j at a front view of the two members 24 and 24 i with the first measuring scale 22 a release (Fig. 8a ). Above the link 24 h are the remaining, folded links 24 a - 24 g ( Fig. 8b). As the rear view according to FIG. 8c shows, the second measuring scale 22 b begins on the back from the first meter rod end 21 a with the meter stick according to the invention with the value 200 and runs to smaller numbers similar to the known meter stick according to FIG. 11c. In contrast, the composition of the links 24 a- 24 j on the swivel joints 23 a- 23 i differs from that of the known yardstick. This makes it easy to read the scale in this condition, even in tight spaces.

An essential advantage of the embodiment shown in FIGS. 6-8 that the individual meter bar members 24 a-24 j can be prepared as for the known meter rule in an identical manner. Merely the assembly at the swivel joints 23 a- 23 i in the course of the manufacture has to be changed. With the invention, therefore, a very advantageous effect for the user can be achieved without the need for complex changes in manufacture.

All lengths and units of measurement in the description above serve only to explain examples and do not constitute prescribed absolute information restricting the invention It can both other units of measure as well as others Divisions are used without departing from the scope of the invention leave.

Claims (4)

1. Collapsible length measuring device with a plurality of rigid members ( 14 a- 14 j) with a predetermined length, which are connected at their ends via rotary joints ( 13 a- 13 i) in pairs so that the measuring device can be opened to different lengths, a first Dimension scale ( 12 a) on the front and a second measurement scale ( 12 b) on the back, the first measurement scale ( 12 a) being arranged on the front so that the dimensions from a first end ( 11 a) of the measuring device ( 10 ) to the second end ( 11 b) of the measuring device ( 10 ) with increasing numerical value from minimum to maximum measured value, characterized in that
the individual links of the length measuring device are connected to one another at the swivel joints in such a way that when looking at the front, one link with higher scale values is always below the adjacent link with the lower measured values, and
the second scale ( 12 b) is arranged on the back so that the dimensions from the first end ( 11 a) of the measuring device ( 10 ) to the second end ( 11 b) of the measuring device ( 10 ) with increasing numerical value from the minimum to the maximum measured value to run. 2. Collapsible length measuring device with a plurality of rigid members ( 14 a- 14 j) with a predetermined length, which are connected in pairs at their ends via swivel joints ( 13 a- 13 i),
that the measuring device can be opened to different lengths, a first scale ( 12 a) on the front and a second scale ( 12 b) on the back, the first scale ( 12 a) being arranged on the front so that the dimensions run from a first end ( 11 a) of the measuring device ( 10 ) to the second end ( 11 b) of the measuring device ( 10 ) with an increasing numerical value from the minimum to the maximum measured value, characterized in that
the individual links of the length measuring device are connected to each other so that when looking at the front side a link with higher scale values is always below the adjacent link with the lower measured values, the second scale ( 12 b) is arranged on the back so that the Measure numbers from the first end ( 11 a) of the measuring device ( 10 ) to a predetermined point on the measuring device ( 10 ) with increasing numerical value from the minimum to the intermediate value, which corresponds to the predetermined point on the second scale ( 12 b), and
that a third scale ( 12 c) is formed on the back so that the dimensions run from the second end ( 11 b) of the measuring device ( 10 ) to the predetermined location on the measuring device ( 10 ) with increasing numerical values from the minimum to the intermediate value, which corresponds to the predetermined position on the third scale ( 12 c),
the top-bottom orientation of the numbers on the third scale ( 12 c) is preferably the same as the top-bottom orientation of the numbers on the second scale ( 12 c). 3. Collapsible length measuring device according to claim 2, characterized in that the second and third measuring scales ( 12 b, 12 c) partially or completely overlap, ie at least one of these measuring scales goes beyond the intermediate point. 4. Collapsible length measuring device with a plurality of rigid members ( 24 a- 24 j) with a predetermined length, which are connected in pairs at their ends via rotary joints ( 23 a- 23 i) so that the measuring device can be opened to different lengths, a first one Dimension scale ( 22 a) on the front and a second measurement scale ( 22 b) on the back, the first measurement scale ( 22 a) being arranged on the front so that the dimensions from a first end ( 21 a) of the measuring device ( 20 ) run to the second end ( 21 b) of the measuring device ( 20 ) with increasing numerical value from the minimum to the maximum measured value, and the second scale ( 22 b) is arranged on the back so that the dimensional figures from the second end ( 21 b) of the Measuring device ( 20 ) run to the first end ( 21 a) of the measuring device ( 20 ) with increasing numerical value from the minimum to the maximum measured value, characterized in that the individual elements ( 24 a - 24 j) the length measuring device on the swivel joints ( 23 a- 23 i) are connected to one another in such a way that a link with higher scale values always lies above the adjacent link with the lower measured values.