DE202022002197U1 - folding rule - Google Patents

Abstract

Folding ruler (10) with a large number of measuring elements (12, 14, 16), the folding ruler (10) extending along a measuring axis M in the useful configuration and having a scale (20) along the measuring axis M, the measuring elements (12, 14, 16) perpendicular to the measurement axis M in a transverse axis Q, characterized in that the scale (20) includes digits and the reading direction L of the digits is parallel to the transverse axis Q.

Description

field of invention

The present invention relates to a folding rule, i.e. a rule consisting of two or more links. Typically, these members can be placed in a transport position and in a use position. A typical example of a folding rule is a folding rule, which typically has ten sections and typically provides a measuring length of 2 meters in the fully deployed configuration of use.

Background of the Invention

Folding rules and folding rulers in various forms are old. Various suggestions for improvement have been made.

The disclosure document DE 102 18 553 A1 discloses a collapsible folding rule. This folding rule should be labeled in such a way that lengths on solid surfaces can be measured largely without parallax errors, especially when the folding rule is partially folded. A collapsible folding rule is disclosed in which numerical values are arranged on a first side of the folding rule in such a way that they increase in the first counting direction and the first counting direction is oriented such that the lowest numerical value is obscured when the folding rule is fully folded.

The present invention would like to offer an improved folding rule that is particularly easy to read in many measuring positions. The folding rule should achieve good readability, especially when used vertically.

More detailed description

A folding rule according to the invention has a large number of measuring elements. A large number is to be understood as meaning a minimum number of two measuring elements. As a rule, it also has more than two measuring elements, for example four or eight or ten or twelve. The folding rule according to the invention can be made available in the form of a customary folding rule with ten measuring segments. The sensing members are typically slat-shaped sections having a top and bottom in combination with much narrower edge sides.

As a rule, the measuring elements can be moved in relation to one another. In this way, the folding rule can be transferred from a use configuration to a transport configuration. In the transport configuration, the folding rule is more compact overall than in the utility configuration. For example, in the transport configuration, most or all of the sensing members may be arranged substantially parallel to each other and extend approximately the same length. In the useful configuration, the measuring elements are essentially arranged one behind the other in such a way that the folding rule extends in one measuring direction. This measurement direction allows the maximum length to be measured when the links are arranged in the useful configuration. The measuring axis usually runs along the longest mirror symmetry axis of the folding ruler.

The folding rule has a scale in the measuring direction, also referred to herein as a measuring scale. The measuring scale typically includes an increasing series of numbers, say from 1 to 199, to measure a length of 2 meters. As a rule, the first number and the last number, in the example 0 and 200, are left out for reasons of space. The scale can also have a unit of measurement, but the unit of measurement can also be omitted. A standard folding rule measures in centimetres.

The measuring elements essentially extend along a measuring axis (herein also: “in the measuring direction”) and have a transverse axis perpendicular to the measuring direction. A useful gauge will measure between 5 and 20mm along the transverse axis (also referred to herein as "transverse"). In the longitudinal direction it can z. B. 10 cm or 20 to 24 cm.

The numbers on the scale are made up of digits, for example the 12 for a length of 12 cm on a folding rule, the digits 1 and 2. These digits have a reading direction. For example, numbers in a book line would be arranged so that the reading direction is left to right.

According to the invention, the folding rule is provided with a scale in such a way that the reading direction of the digits is parallel to the transverse direction of the measuring elements.

In principle, two reading directions are conceivable, namely from left to right or from right to left. It has proven useful if the reading direction, measured clockwise, is oriented at 90° to the direction of the increasing number on the measuring scale.

For example, if the scale rises from zero to 200 from the floor and the reading direction then goes from left to right, this is good.

For some situations, the reverse direction is also useful, i.e. a reading direction that is offset clockwise by 270° to the direction of ascending scale notations.

This choice of reading direction appears to be a small change in the measuring scale of a folding rule, but has proven to be extremely beneficial. A folding rule is very often used to measure heights. Even if the folding rule were used to measure a height of perhaps 1.60 meters above the ground, i.e. at the eye level of a typical user, the reading is uncomfortable. The user is very used to reading digits only in the reading direction. Theoretically, reading in a different direction can be done by not capturing the digits in the reading direction. In many cases, however, the reader will tend to bend their head as this seems more comfortable. A slight inclination of the head is possible at the exemplary reading height of 1.60 meters. A complete inclination of the head in order to achieve the usual reading direction is anatomically almost impossible even at this reading height. Things get even more uncomfortable and difficult at other reading heights, around 1.00 meters or 2.00 meters.

Interestingly, the advantage of the new type of scale reading also applies to horizontal measurements. When measuring horizontally, for example the width of a shelf by placing a folding rule on top of the shelf, the conventional scale, with the reading direction in line with the measuring direction, seems convenient. This is also readily the case. However, it should be considered that the scale according to the invention can also be easily read when the folding rule is oriented horizontally. This can be done by slightly rotating the body around the longitudinal axis. This rotation is completely unproblematic, on the one hand because the human anatomy easily allows it, on the other hand because the foot position on the floor can usually be adjusted in the direction of a comfortable reading. The feet can therefore be oriented entirely or at least slightly in the direction of measurement.

This was not taken into account in the previous scale orientation. The convenience of a different scale orientation for horizontal readings and the inconvenience of the different scale orientation for vertical readings do not appear to have been adequately balanced. The scale reading according to the invention has great advantages in the majority of cases when a folding rule is typically used.

It has proven to be advantageous if the folding ruler can assume a transport configuration in which at least two measuring elements lie parallel one above the other. It is also particularly useful if all measuring elements are parallel to one another in the transport configuration. It is therefore advantageous if the measuring elements of a folding ruler can be rotated in relation to one another.

It is also advantageous if the measuring elements can be locked in a measuring position. This allows the usage configuration of the folding rule to be taken more stably. It is also useful if the measuring elements can be locked in the transport position. A soft and easily releasable locking is advantageous. Such locking can be achieved if the measuring elements are connected by spring joints in the folding ruler.

A folding rule that has a first measuring element with a scale that is visible from the outside is particularly useful. Such a first measuring element is arranged in the measuring direction at the end or beginning of the folding rule. An advantage of a scale that is visible from the outside is that the user can immediately obtain information about the type of scale, for example the unit of measurement and the type and number of inscriptions. This is particularly beneficial when the scale falls short of conventional expectations in some way.

In particular, a folding rule is expedient in which the first measuring element has an abutting end and a hinged end and has the scale from the abutting end to the hinged end. The abutting end is the end of the folding rule where the distance 0 is measured. Such an abutment end can be reinforced by an abutment cap, for example made of metal. Opposite the abutting end there may be a hinged end by which the first measuring member is suitably connected to the next measuring member. The term joint end is also used here when no joint is provided, but rather another possibility of connecting the first measuring element to further measuring elements. A scale that ascends from lug end to joint end is one in which the small numbers are closer to the lug end and the large numbers are closer to the joint end. For example, the 0 can be expediently provided at the abutting end.

Alternatively, a folding rule can also be expedient in which the first measuring element has a scale that is visible from the inside. In this case it can be useful if the scale descends from the abutting end to the joint end. In other cases, the scale may rise from the lug end to the joint end.

A folding ruler with a scale that extends to the edge of the measuring elements is also useful. Such scale marks can extend over the entire width of the measuring elements. As a rule, they run exactly perpendicular to the direction of measurement.

A folding ruler with shorter scale lines between the scale lines running across the entire width of the measuring elements is also useful. Such scale marks can expediently extend from the edge of a measuring element over approximately one third of the width of the measuring element.

A folding rule that has a usage configuration and is at least 1.50 meters long in this usage configuration is expedient. A length of at least 2.00 meters, 2.50 meters or 3.00 meters is also advisable. Such a folding rule is particularly well suited for height measurements. The labeling of the scale according to the invention facilitates such a height measurement.

In principle, it makes sense to make the measuring elements of a folding ruler out of wood, metal or plastic.

• 1 zeigt eine Seitenansicht eines erfindungsgemäßen Gliedermaßstabs
• 2 zeigt eine Aufsicht auf das erste Messglied eines Gliedermaßstabes nach dem Stand der Technik
• 3 zeigt eine korrespondierende Aufsicht auf einen erfindungsgemäßen Gliedermaßstab, in dem ebenfalls das erste Messglied sichtbar ist

Further features, but also advantages of the invention, result from the drawings listed below and the associated description. In the figures and in the associated descriptions, features of the invention are described in combination. However, these features can also be included in other combinations by an object according to the invention. Each disclosed feature is therefore also to be regarded as being disclosed in technically meaningful combinations with other features. Some of the illustrations are slightly simplified and schematic.

• 1 shows a side view of a folding rule according to the invention
• 2 shows a top view of the first measuring element of a folding rule according to the prior art
• 3 shows a corresponding top view of a folding rule according to the invention, in which the first measuring element is also visible

1 shows a typical folding rule 10 in a side view. This consists of a series of measuring elements, in particular the first measuring element 12 and the last measuring element 14 provided at the other end of the folding rule. Intermediate measuring elements 16 are provided in between. This folding rule has a total of 10 measuring elements, as is quite common for folding rules in the form of folding rules. The first measuring element 10 and the last measuring element 14 are shorter than the remaining measuring elements. The measuring elements are connected by spring joints 18.

These spring joints allow the measuring elements to be rotated relative to one another perpendicularly to their main plane of extent.

The figure shows the folding rule in the transport position. In this position, all measuring elements are on top of each other. The folding ruler 10 can be moved into a usage position by twisting the measuring elements with the help of the spring joints 18 . Then typically several or all measuring elements are arranged one behind the other and connected to one another by the spring joints.

2 shows the first measuring element 12 of a folding rule according to the prior art in plan view. Such a folding rule is therefore not part of the invention.

3 shows a folding rule according to the invention in the same plan. The first measuring element 12 is again visible. This measuring element has a scale 20 .

The first measuring element 10 extends along the measuring axis M and perpendicular to it in the transverse axis Q.

The scale 20 consists of numbers, which in turn consist of digits. These digits are arranged in a reading direction. The reading direction is marked by the arrow L in the example of the number 5.

In a folding rule according to the invention, the reading direction L is parallel to the transverse direction of the measuring links.

It has proven to be useful if the reading direction - as seen in the ascending direction of the scale - runs to the left. That means using the example of 3 that if the line of sight is from the end of the first measuring element in the direction of 1, then 2 and then 3, the reading direction is oriented to the left. Alternatively, the reading direction can also be oriented to the right.

Overall, one can see how an easy-to-read and easy-to-manufacture folding ruler can be produced, which is particularly suitable for convenient measurement in the vertical direction.

reference list

10

folding rule

12

first measuring element

14

last measuring element

16

intermediate measuring element

18

spring joint

20

scale

22

abutting

24

joint end

M

measuring axis

Q

transverse axis

L

reading direction

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 10218553 A1 [0003]

Claims (14)

Folding ruler (10) with a large number of measuring elements (12, 14, 16), the folding ruler (10) extending along a measuring axis M in the useful configuration and having a scale (20) along the measuring axis M, the measuring elements (12, 14, 16) perpendicular to the measurement axis M in a transverse axis Q, characterized in that the scale (20) includes digits and the reading direction L of the digits is parallel to the transverse axis Q. Folding ruler (10) according to the preceding claim, whose measuring elements (12, 14, 16) can be rotated in relation to one another. Folding rule (10) according to one of the preceding claims, which can assume a transport configuration in which at least two measuring members (12, 16) lie parallel one above the other. Folding ruler (10) according to one of the preceding claims, whose measuring elements (12, 14, 16) can be locked in a measuring position. Folding ruler (10) according to one of the preceding claims, whose measuring elements (12, 14, 16) can be locked in a transport configuration. Folding ruler (10) according to one of the preceding claims, whose measuring elements (12, 14, 16) are connected by spring joints (18). Folding ruler (10) according to one of the preceding claims, which has a first measuring element (12) which is arranged at one end of the folding ruler (10) and has a scale (20) which is visible from the outside. Folding rule (10) according to the preceding claim, in which the first measuring member (12) has an abutment end (22) and a hinge end (24) and the scale (20) rises from the abutment end (22) to the hinge end (24). Folding rule (10) according to one of the preceding claims, which has a first measuring element (12) with a scale (20) visible from the inside. Folding rule (10) according to the preceding claim, wherein the first measuring member (12) has an abutment end (22) and a hinge end (24) and the scale (20) descends from the abutment end (22) to the hinge end (24). Folding ruler (10), the scale of which has scale lines running along the entire transverse axis Q of the measuring elements (12, 14, 16). Folding ruler (10) according to the preceding claim, in which intermediate scale lines which do not run over the entire transverse axis Q are provided between the scale lines which run over the entire transverse axis Q. A folding rule (10) as claimed in any one of the preceding claims which has an in-use configuration and has a length of at least 1.5 meters in the in-use configuration. Folding ruler (10) according to one of the preceding claims, whose measuring elements (12, 14, 16) are made of wood, metal or plastic.

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