ES1282580U - Gap meter (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

A gap meter (111), comprising: - a central body (112) with an opening (113) arranged in the middle of the central body (112), where the opening (113) is configured as meter grip element; and - a plurality of fingers (114), extending radially outward from the central body (112), forming a meter geometry in star shape, where the plurality of fingers (114) are connected in its part proximal to the central body of the meter (112), where each finger (114) comprises at least one metering section (115) arranged in the end end of the respective finger, where the measurement width (116) of the at least one measuring section (115) of each finger is different from each other, where the at least one measurement section (115) of each finger is configured to determine the dimensions of a hollow space existing between assembly parts; characterized in that the space meter (111) comprises a first material and a second material, where the first material is a material that has a hardness between 30 and 35 Shore A, where the at least one measuring section (115) is composed by a sandwich type structure (411) where the second material is covered, at least partially, by the first material, so that a contact between the assembly parts and the space meter (111) is produced by means of the first material; where the second material is a material that has a hardness between 74 and 75 Shore D, and; where the sandwich structure (411) of the at least one metering section (115) is composed of an upper section (412), a lower section (413) and an intermediate section (414), where the upper section (412) and the lower section (413) comprise the first material; and the intermediate section (414) comprises the second material. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Gap meter

Object of the invention

The object of the present invention resides in obtaining a measuring element, used, for example, in the sector of manufacturing and assembly of motor vehicles, which avoids scratching the contact surface on which a measuring action is carried out. For this, within the same structure, two materials with different mechanical properties coexist, which provide robustness to the structure and provide the right conditions so that no damage occurs.

Prior state of the art

Today, the use of space gauges is common. These measurement tools are used in a variety of shapes and designs. The space gauges are designed to carry out independent measurements of the existing spaces between assembled parts and to verify the tolerance levels between said parts in series, where the measuring element and the body on which the measurement is made are permanently in contact in contact with each other. the moment to perform the action of measuring. Generally, space gauges are collapsible tools that comprise individual test measurements, that is, each gap gauge encompasses a single unit of measurement. Consequently, it is necessary to have a large number of meters available for the different measurement and test points. This fact on some occasions does not guarantee the uniformity and reproducibility of the measurements of the space between pieces. Additionally, most of these designs are made of plastic or metal materials with sharp edges that tend to damage the surface on which the measurement is being made.

For an example, in the case of the automotive sector, vehicles have parts or coatings separated by spaces that for optical and functional reasons must be verified. Thus, in order to check that the space between the different assembly parts is within the established vehicle manufacturing limits, a verification of the separation between parts or coatings must be carried out. Bliss Verification is done by using measurement tools such as a gap gauge. Therefore, since it is a verification procedure, the measurement tool to be used must have the highest possible precision. In addition, since it is in direct contact with the body that is being measured, it is necessary to avoid damaging the part on which the space parameter to be defined is to be obtained.

Continuing with the example of application of said meters in the automotive sector, it is common to use them to measure the space between moving parts, or between a moving part with a fixed part. Thus, there must be an empty space free of rigid components that allows movement between the two assembly parts. Thus, to cite an example, this space may exist between a front door and a fender, or a front door and a rear door. This space must be greater than a minimum value, which allows its relative movement, but less than a maximum value, in order to maintain a suitable appearance and design. To carry out these measurements, a space meter is used, which is inserted into the space between the two assembly parts. This operation is commonly manual, performed by an operator. On many occasions, during the manipulation and introduction of the gap gauge into said grooves, there is contact between the gap gauge and the parts or components of the vehicle, with the risk of damaging the visible surfaces of said components.

Space gauges are known, which comprise the features included in the preamble of claim 1.

Such is the case, for example, of that described in patent document EP2963378, which describes a gauge that is characterized by the fact that it consists of a compact set in the shape of a star with angular or rounded tips, with a round or round opening. polygonal in the middle, with the individual points of the compact star shape for measuring joints and gaps.

The gap gauge described in said patent document intends to guarantee, by means of a compact object, the thickness measurement, the precision of the measurement of joints and gaps without causing any damage, as well as the repeatability with the choice of the tips of designated measurement. The quoted gap gauge consists of 3 to 10 measuring tips, which have one to two (possibly three) defined dimensions, with a clear numerical identification, as well as a round or polygonal opening in the center of the body. They can be described in such a way that they are compact of a soft and flexible material, which provides an accurate, uniform and repeatable measurement of gaps and crevices without any possibility of damaging the object on which the measurement is made, including the external surface. However, although the existence of a compact gap gage with measurement tips of a soft and flexible material is noted for accurate and repeatable measurement of joints and gap without causing minimal damage to the measurement object, but no reference is made to the materials from which the meter structure is formed. So, if the user when making measurements inside the grooves using the measuring tips, places the gap gauge at a certain inclination, not only the measuring leads but also the gap gauge itself would come into contact. with the surface to be measured. Contact between the gap gauge and the surface to be measured, either by dragging on it or simply by resting on the body while the measurement action is being carried out, could damage the surface, causing scratches or gouges, especially on pieces with final finish, such as painted or polished. In addition, the fact that the measurement tips are made of a soft and flexible material does not assure us of the robustness of their structure, so an excess of deformation at the time of measurement could cause deviations in the measurements made, therefore that the precision of the measurements is not assured.

It is therefore necessary to offer an alternative to the state of the art that covers the gaps found in it, by providing a space meter that does not suffer from the drawbacks of the already known measuring elements, in particular that it lacks, among others, of the inconveniences indicated above.

Explanation of the invention

The aim of the present invention is to provide a space meter that solves the aforementioned drawbacks and has the advantages that will be described below.

To this end, the present invention concerns a gap space meter, comprising:

• a central body with an opening arranged in the middle of the central body, where the opening is configured as a gripping element for the meter; Y

• a plurality of fingers, extending radially outward from the central body, forming a star-shaped geometry of the meter, where the plurality of fingers are connected in their proximal part to the central body of the meter, where each finger comprises at least a measurement section arranged at the end end of the respective finger, where the measurement width of the at least one measurement section of each finger is different from each other, where the at least one measurement section of each finger is configured to determine the dimensions of a hollow space between pieces of assembly;

Unlike the gap gauges known in the state of the art, in that of the present invention, the gap gauge typically comprises a first material and a second material, where the first material is a soft material, where the at least one measuring section is composed of a sandwich-type structure, where the second material is covered, at least partially, by the first material, so that a contact between the assembly parts and the space meter is produced by means of the first material.

By "sandwich structure" is understood a structure consisting of at least two layers of different materials, joined together to form a single structure. This type of structure is used when it is required to achieve certain type of characteristics in the structure, such as lightness or rigidity, which cannot be satisfied with current materials. That is, the same body has different layers where materials with different properties are in contact. In the example of the present invention, the sandwich-like structure is formed by a second material, which is covered by a first soft material in the areas susceptible to contact with the assembly parts to be measured. Thus, the fact that the measurement sections present this type of structure is achieved by means of a second material, which provides structural rigidity, maintaining the flexibility of the measurement sections, facilitating the entry of the measurement section in those Gaps between assembly parts ensuring repeatability of thickness and thickness measurements.

In addition, the fact that the contact between the assembly part and the meter is made through the first material or soft material prevents any type of damage to the part itself, such as for example scratches or gouges, especially on pieces already finished superficially, such as painted or polished pieces. "Soft material" is understood as a material that is easily deformable or alters its shape when an external force from another body is exerted on it.

For ergonomic reasons, it is also advantageous for the central body to have an opening in the center of the body as it allows it to be held, for example, if the user who is going to make the measurements holds the measurement by clamping the thumb and index finger through of the opening. It is understood that other geometries can also be used and are suitable to facilitate the grip of the meter, such as slits made both in the upper and lower surface of the central body, arranged in the middle of said central body.

The space meter according to the invention has a star-shaped geometry with preferably six fingers. By star-shaped geometry in the present invention is meant a structure formed by fingers or extensions in radial shape, that is, extending from a center of the central body. Each one of the fingers is suitable to have the useful measuring sections for assembly parts, in addition for ergonomic reasons it facilitates the handling of the space meter by the user.

In a preferred embodiment of the invention, the second material is a hard material. Thanks to the fact that the second material is a hard material that is covered, at least partially, by a soft material, it is possible to keep the dimensions of the space meter constant, as well as its structural stability. Thus, a measurement element is achieved where the main structure presents a certain rigidity while maintaining flexibility in the measurement areas. Said second hard material is such that it allows, in the face of blows, pressures or other types of external forces on the space meter, both the central body and the plurality of fingers, their initial geometry is maintained, so that repeatability is ensured. in the measurements made.

"Hardness" is understood as the resistance of the material to localized plastic deformation on its surface, when external forces are applied by another body on it.

There are different methods and tools to measure the hardness of materials, in particular, the hardness parameters of the first material and the second material will be determined by Shore hardness, which allows calculating the elasticity of an element when another element is dropped on it or is try to pierce it with something harder. Shore hardness is a scale for measuring the elastic hardness of materials, which is measured in parameters 0 to 100 on the A or D scales, where the letter A is used for flexible fonts and the letter D for rigid fonts.

In a first example of the invention, the first material has a hardness ranging from 30 to 35 Shore A, while a second material has a hardness between 74 to 75 Shore D.

According to an exemplary embodiment, the first material has a surface roughness, the fact that the first material presents certain deformations or irregularities on its outer surface favors the adhesion of the space meter of the areas that comprise said first material on the pieces of assembled that measurements are made. Furthermore, deviations are avoided when thickness and thickness measurements are made, improving precision and ensuring reproducibility in the measurements.

For an implementation of said embodiment, the second material is a material resistant to change in shape under the action of external forces. "Strength" is understood as the ability of bodies to resist external forces without breaking. So that when the measurement of the assembly part is carried out, although there are external forces that are carried out on the body to proceed with the measurement action, the areas that are covered by the second material will experience a slight deformation without presenting changes. in its main structure. Advantageously, a robust structure is obtained that will make it possible to obtain measurements with greater accuracy and precision. Additionally, the lifetime of the space meter structure is increased.

According to a first embodiment, the central body and the plurality of fingers are composed of the second material. Consequently, thanks to this uniformity of distribution of the second material on the surface of the central body and on the surface of the plurality of fingers, a robust and hardly deformable structure is achieved. especially when measurements are being carried out, ensuring their traceability and repeatability.

According to a first embodiment, the base of the central body comprises a covering of the first material. In this way, the base or lower surface of the central body will present a covering of soft material, facilitating the grip by the operator and avoiding scratching other parts or components, especially when the space meter is supported against other surfaces.

According to a second embodiment, the base of the plurality of fingers comprises a covering of the first material. Consequently, the part of the fingers that comprise the measuring sections adopts greater flexibility in its structure, thereby facilitating the insertion of the measuring sections inside the gaps without causing damage to the assembly part. A central body made of a second material is thus obtained, providing the measure with rigidity and good mechanical behavior. On the contrary, the plurality of fingers will have a central structure formed by said second material but covered, both by the upper surface and the lower surface, of the first soft material. In this way, the surfaces of the measurement sections capable of contacting other parts will be covered with said soft material, avoiding causing damage to the assembly parts to be measured.

According to a third embodiment, the base of the central body and the base of the plurality of fingers are comprised in the same plane, forming a substantially flat meter support surface, where the base of the central body and the base of the plurality of fingers comprise a covering of the first material. So that a first material is uniformly distributed over the entire lower surface of the meter and both the central part and all the fingers, including the measuring sections, are covered by a soft material. Consequently, when the surface of the gap meter rests on the surface to be measured, that is, when both surfaces come into contact, the surface on which we are measuring does not experience any type of damage from the meter. A central body composed of a second material is thus obtained, providing the meter with rigidity and good mechanical behavior, where the base of the same is covered with the first soft material. Similarly, the plurality of fingers will have a central structure formed by said second material but covered, both by the upper surface as well as the lower surface, of the first soft material. In this way, the surfaces susceptible to contact with other parts, both of the central body and of the fingers, will be covered with said soft material, avoiding causing damage to the assembly parts to be measured.

According to any of the aforementioned embodiments, the sandwich-like structure of the at least one metering section is composed of an upper section, a lower section and an intermediate section, where the upper section and the lower section comprise the first material; and the middle section comprises the second material. That is, in the measurement sections, a second material is covered by a first material in the upper and lower section, said sections being capable of contacting other pieces to be measured, so that the structural rigidity and flexibility of the the measuring section ensuring the reproducibility of the measurements. As an example, the structure of the measuring section is composed of:

• an upper part, which coincides in the same plane with the meter surface and comprises the upper section of the structure,

• a base, which coincides in the same plane with the base of the meter and comprises the lower section of the structure,

• lateral ends, which are located on the apparently visible surfaces on the sides of the measuring sections, and form part of the intermediate section between the top and the base, and

• front part, which is located at the front of the metering section, forms part of the intermediate section between the top and the base.

Therefore, both the front and the sides of the measurement sections are at least partially covered by the upper part and the base, where the thickness and thickness of the measurement sections is uniform throughout the meter structure. Thanks to this uniformity in the structure, it is possible to ensure the precision in the measurements and their handling in an optimal way.

In general, the ends of the at least one measuring section of each finger comprise rounded edges, which replace the sharp edges that were conventionally used. Thanks to the presence of rounded edges, it is avoided to cause gouges or scratches on the surfaces that are being measured.

According to all the above, the measuring section of each finger comprises at least one step, where the at least one step is arranged on the upper surface of the meter, where the at least one step is configured and arranged to define at least two widths. measurement in each measurement section. The step divides the finger into two different measurement sections, thus being able to increase the number of measurements to be carried out with the meter, for the same number of fingers. It is noted that each measurement width is defined by the distance between the upper and outer surface of the measurement section and the lower and outer surface, that is, the base, of said same measurement section. Both the upper surface and the lower surface are parallel to each other. In particular, the width dimensions are identified numerically in the central body of the meter, where the gradation of each step is 0.5 mm and the defined thickness dimensions are preferably 1.5 to 7 mm. Therefore, the thickness and thickness of each measurement section that comprise the plurality of fingers of the hollow space meter, is different depending on the measurement gradation associated with it.

For a first embodiment of the invention, the meter is obtained by means of a process of molding the first material and the second material in the molten state by horizontal deposition section by section of said first material and said second material, obtaining the meter in a single 3D printing process. Advantageously, the use of this technique allows the meter to be produced in a simple way in a single stage, fast, economical and precise, ensuring reproducibility in the pieces. In addition, it allows the use of a wide variety of materials for the production of parts. Particularly for the meter according to the invention, it is preferable to use polymeric materials, such as photopolymers, more specifically resins, which allow us to obtain a flexible and rigid meter contained in different planes.

For a second embodiment of the invention, a meter is obtained by means of an injection of the second material, forming the central body and the plurality of fingers, and an over-injection of the first material arranged covering the second material and forming the sandwich-like structure, said overinjection being carried out in the at least one measuring section arranged at the end end of the respective finger. In particular, the process described is a process that takes place in two stages, a first stage where the injection of a second material takes place on an injection mold and a second stage of overinjection of the first material on the second material, so through a single process produces a structure in which two materials with different properties coexist, which gives us a structure with greater mechanical resistance. So, if said structure is found in the measurement sections, a robust structure that is difficult to deformation but flexible is achieved that provides reliability and reproducibility in the measurements.

Surprisingly, the present invention provides a meter that incorporates materials with properties within the same structure, preferably a hard material and a soft material, where the material in contact with the assembly part avoids causing damage to other parts or components when they are being made. the measures. In addition, the described meter can be obtained by different simple obtaining processes that ensure reproducibility in its manufacture.

Brief description of the drawings

The above and other advantages and characteristics will be more fully understood from the following detailed description of some exemplary embodiments with reference to the attached drawings, which should be taken by way of illustration and not limitation, in which:

Figure 1 shows an elevation view of the upper plane of the space meter, according to the present invention.

Figure 2 is an elevation view of the base or lower plane of the space meter, according to the present invention.

Figure 3a is a vertical sectional view of the space meter, according to a first embodiment of the present invention.

Figure 3b is a vertical sectional view of the space meter, according to a second embodiment of the present invention.

Figure 3c is a vertical sectional view of the space meter, according to a third embodiment of the present invention.

Figure 4 is a sectional view in vertical section of the measurement section, according to the present invention.

Detailed description of some examples of realization

Next, a preferred embodiment of the claimed void meter is described with reference to Figures 1 to 4.

Figure 1 illustrates in detail a view of the upper plane of a gap meter (111), which is formed by:

• a central body (112) with an opening (113) arranged in the middle of the central body (112), where the opening (113) is the area through which the user grasps the space meter (111) to perform measurements . As can be seen, the surface of the central body (112) which is delimited on the inside by the rounded opening (113) and on the outside by a plurality of fingers (114).

• a plurality of fingers (114), preferably 6 fingers, although it can be any other value, extending radially outward from the central body (112), forming a star-shaped meter geometry. The plurality of fingers (114) are connected in their proximal part to the central body (112) of the space meter (111), that is, the proximal part of the plurality of fingers (114) coincides with the delimitation on the outside of the body central (112). Furthermore, at the ends of the plurality of fingers (114) we find at least one measuring section (115). The measurement width (116) of the at least one measurement section (115), preferably two measurement sections (115) for each finger (114), is defined and marked numerically on the surface of the plurality of fingers (114) for precise measurement of joints and gaps, increasing in 0.5mm steps (or other defined dimension) from the smallest dimension 1.5mm to the largest dimension 7mm.

The star-shaped configuration of the space meter (111) and, especially the existence of six fingers (114), makes it possible to guarantee the symmetry of the space meter (111). In this way, the manipulation by the operator of the space meter (111) is facilitated.

Similarly, it is observed that the measurement sections (115) are arranged at the ends of each of the fingers (114). The operator, manipulating the gap meter (111), holds the device through the central opening (113) and rotates it until the required measurement width (116) is found. Subsequently, it introduces the measuring section (115) of the corresponding finger (114) into the gap between the two assembly pieces to be measured. It should be noted that only the measurement section (115) is inserted into said hole, the rest of the body of the space meter (111) remaining outside the assembly parts.

As can be seen, for example, in Figure 2, where an elevation view of the base of the space meter (111) is shown, it can be seen that the space meter (111) has a star-shaped geometry, formed by the base of the central body (211) and the base of the plurality of fingers (212). The base of the central body (211) has an outer part, delimited by each one of the fingers forming a structure with hexagon geometry, and an inner part delimited by an opening (113) in the middle that has a circular or round shape. The base of the plurality of fingers (212) coincides in its inner part with the outer part of the base of the central body (211). It can be seen that, in the outermost area of the plurality of fingers (114), these have rounded edges (213).

For the embodiments illustrated in Figures 3a, 3b and 3c, a vertical sectional view of the space meter is shown where the different configurations of the central body (112) and the plurality of fingers (114) are observed. In all the exposed representations, the central body (112) and one of the fingers (114) are represented with their corresponding measurement section (115). Given the symmetry of the space meter (111), represented by a vertical broken line arranged in the center of the opening (113), the representation of the finger (114) arranged at the opposite end is omitted, thus simplifying the representation. In said figures a detail of the measurement widths (116) of a measurement section (115) can also be seen. Specifically, the step that separates the different measuring widths (116) can be seen.

Thus, in said Figures 3a, 3b and 3c the plurality of fingers (114) are represented, being formed by a second material or hard material, which is represented in white. On the contrary, the first material or soft material is represented in black. In the three sections shown in Figures 3a, 3b and 3c, it can be seen that at the end of the finger (114), where the measurement sections (115) are located, they are formed of the first material, represented in black, which represents the material substantially soft.

As can be seen in Figure 3a, for a first embodiment of the invention it can be seen how the base of the plurality of fingers (212) and the base of the central body are made of different materials, where the black areas represent a substantially hard material. and the white areas a substantially soft material, so that for the present representation the base of the central body (211) is composed of a substantially soft material and the base of the plurality of fingers (212) is formed of a substantially hard material. That is, the base of the central body (211) and the central body (112) comprise different materials with different properties, while the base of the plurality of fingers (212) and the plurality of fingers (114) comprise the same material. In this way, a greater grip by the user of the meter (111) is allowed, in addition since the base of the central body (211), depending on the inclination with which the user makes the thickness and thickness measurements, in In most cases, it is in contact with the surface of the assembly part on which inter-part space measurements are being made, thus avoiding scratches on the surface when measurements are made.

For a second embodiment of the invention, as shown in figure 3b, and in the same way as in the configuration shown in figure 3a, it can be seen as the base of the plurality of fingers (212) and the base of the central body (211) are formed by different materials, where the black areas represent a substantially soft material and the white areas a hard material, so that for the present representation the base of the central body (211) is composed of a substantially soft material. hard, providing the body with rigidity and good mechanical behavior, while the base of the plurality of fingers (212) is formed of a soft material. That is, for this configuration, the base of the central body (211) and the central body (112) comprise a single material, on the contrary, the plurality of fingers (212) will have a central structure formed by a substantially hard material. represented in white but covered, both on the upper surface and on the base of the plurality of fingers (212), by a substantially soft material represented in black. In this way, the surfaces of the measurement sections (116) susceptible to contact with other parts will be covered with said soft material, avoiding causing damage to the assembly parts when carrying out the measurement operations.

For a third embodiment of the invention, by way of example, as shown in figure 3c, it is observed that both the base of the plurality of fingers (212) and the base of the central body (211) are composed of a substantially soft material, represented in black, that extends throughout the base of the space meter (111). Thus, both the base of the plurality of fingers (212) and the base of the central body (211), including the upper part of the measurement sections (115), are covered by a substantially soft material. In summary, the entire meter base (111) and the upper surface of the measurement sections (116) are formed of a substantially soft material. Consequently, since the base of the meter (111) is made of a substantially soft material, represented in black, when the surface of the gap meter rests on the surface to be measured, the piece to be measured does not experience any type of damage by part of the meter (111). Similarly, the plurality of fingers (114) will have a central structure formed, both by the upper surface where the measurement sections (115) are located and by the base of the plurality of fingers (114), of soft material. That is, both the measuring sections (115) and the base of the central body (211) and the base of the plurality of fingers (212), which are the surfaces with the greatest susceptibility to contact with other parts, are covered with the material. soft represented in black, avoiding causing damage to the assembly parts to be measured.

A preferred configuration of the measurement section (115) is shown in Figure 4. It shows a sandwich-type structure (411) of a measurement section (115), where independent sections are shown to differentiate the different materials. that are part of the measurement sections (115), each change of material being defined by a different coloration. As described above, the areas delimited by a black color represent a substantially soft material, while the areas that appear in white represent a substantially hard material. The structure of the measuring section (115) is found defined by thinner black lines. According to the configuration shown in figure 4 it is observed:

• an upper section (412)

• a lower section (413)

• an intermediate section (414)

The lower section (413) coincides in the same plane as the base of the plurality of fingers (212), the intermediate section (414), is encapsulated between the upper section (412) and the lower section (413) so that it acts as a structural element for the whole body. In a preferred embodiment, the upper section (412) and the lower section (413) are made of the same material, this material being the first substantially soft material, such as a resin, while the intermediate section (414) is formed of a second material, such as another resin. In particular, when the user is making measurements on the assembly part, the upper section (412) and the lower section (413) are the surfaces that are in contact with the part to be measured.

It is also observed that between the different measurement sections (115) there is a difference in level, represented by a step (415) in the measurement section (115) itself. Each step (415) separates different measurement widths (116). According to one example, the metering sections (115) are formed by two steps (415). Preferably the first measurement width (116) is of a thickness greater than the second measurement width (116), the first measurement width being the closest to the central body (112). In this way, for parts that have a greater separation, the first measurement section (116) will be used and for parts that present a smaller separation, the second measurement section (116) will be used. The measurement units of each step (415) of the measurement sections (115) are represented by numbers on the central body (112) or on the measurement sections (115) themselves, as indicated above.

Although reference has been made to a specific embodiment of the invention, it is clear to a person skilled in the art that the described gap meter is susceptible to numerous variations and modifications, and that all the mentioned details can be substituted by others. technically equivalent, without departing from the scope of protection defined by the appended claims.

List of references of the Figures:

111 Gap Meter

112 Central body

113 Central body opening

114 Plurality of fingers

115 Measurement sections

116 Measuring widths

211 Central body base

212 Base of the plurality of fingers

213 rounded edges

411 Sandwich structure

412 Upper section

413 Lower section

414 Intermediate section

415 Step

Claims (8)

1. A gap meter (111), comprising: • a central body (112) with an opening (113) arranged in the middle of the central body (112), where the opening (113) is configured as a gripping element for the meter; Y • a plurality of fingers (114), extending radially outward from the central body (112), forming a star-shaped meter geometry, where the plurality of fingers (114) are connected proximally to the central body of the meter (112), where each finger (114) comprises at least one measurement section (115) arranged at the end end of the respective finger, where the measurement width (116) of the at least one measurement section (115) of each finger is different from each other, where the at least one measurement section (115) of each finger is configured to determine the dimensions of a hollow space existing between pieces of assembly; characterized in that the space meter (111) comprises a first material and a second material, where the first material is a material that has a hardness between 30 and 35 Shore A, where the at least one measurement section (115) is composed by a sandwich type structure (411) where the second material is covered, at least partially, by the first material, so that a contact between the assembly parts and the space meter (111) is produced by means of the first material; where the second material is a hard material having a hardness between 74 and 75 Shore D, and; where the sandwich type structure (411) of the at least one metering section (115) is composed of an upper section (412), a lower section (413) and an intermediate section (414), where the upper section (412) and the lower section (413) comprise the first material; and the intermediate section (414) comprises the second material. A space meter (111) according to any of the preceding claims, characterized in that the first material has a surface roughness. 3. A space meter (111) to any of the preceding claims, characterized in that the central body (112) and the plurality of fingers (114) are composed of the second material. 4. A space meter (111) according to claim 3, characterized in that the base of the central body (211) comprises a covering of the first material. 5. A space meter (111) according to claim 3, characterized in that the base of the plurality of fingers (212) comprises a covering of the first material. 6. A space meter (111) according to claim 3, characterized in that the base of the central body (211) and the base of the plurality of fingers (212) are comprised in the same plane, forming a support surface of the meter substantially flat, where the base of the central body (211) and the base of the plurality of fingers (212) comprise a covering of the first material. A space meter (111) according to any of the preceding claims, characterized in that the ends of the at least one measuring section (115) of each finger comprise rounded edges (213). A space meter (111) according to any of the preceding claims, characterized in that the measurement section (115) of each finger comprises at least one step (415), where the at least one step (415) is arranged in the upper surface of the meter, where the at least one step (415) is configured and arranged to define at least two measurement widths (116) in each measurement section (115).