DE102013003130A1 - gauge - Google Patents

Abstract

In a measuring device (1) with a shock-sensitive sensor (5), it is proposed to provide at least one damping element (6, 13) of a gel material between a receiving frame (4) carrying the sensor (5) and a housing (3) of the measuring device (FIG. 1) in an interior of the housing (3) to be used to form a shock absorption for the sensor (5) (see Fig. 1).

Description

The invention relates to a measuring device with a housing and a receiving frame arranged in the housing, wherein a sensor of the measuring device is arranged on the receiving frame.

Such measuring devices are known for example from thermal imaging cameras, in which the sensor is designed as an infrared (IR) sensor and held by the receiving frame in a defined orientation.

Especially with thermal imaging cameras, but also with other measuring devices, it has been found that the defined orientation of the sensor on the mounting frame can be affected by impact.

The invention has for its object to increase the robustness against mechanical effects from the outside in a measuring device of the type described above.

To achieve this object, the features of claim 1 are provided according to the invention. In particular, it is thus proposed according to the invention in a measuring device of the type described above, that the receiving frame is held in the housing via at least one damping element made of a gel material. The advantage here is that the composite of sensor and mounting frame against external mechanical shocks can be estimated, since the gel material has good damping properties. With the invention, it is thus avoidable that a mechanical shock from the outside leads to a change in an orientation of the sensor on the receiving frame, since the mechanical impact of the damping element is receivable. Gel materials have been found to be particularly favorable for shock absorption because they prevent particularly damaging or destructive spring-back of the mounting frame. The invention thus advantageously uses the good recovery behavior of gel materials.

In one embodiment of the invention can be provided that the sensor is fixed to the receiving frame. Thus, a particularly firm orientation of the sensor with respect to the receiving frame can be achieved. The degree of fixation strength is tunable to the damping properties of the gel material. Thus, it is possible to ensure that in the case of normally occurring impacts, for example in a case of a normally occurring drop height, the acting impact in the damping element is damped such that the fixation of the sensor on the receiving frame remains practically unimpaired.

In one embodiment of the invention can be provided that the sensor defines an optical or acoustic recording axis. The advantage here is that it is particularly important for sensors that define an optical or acoustic pick-up axis that the aforementioned orientation of the sensor remains unchanged on the receiving frame in order to maintain the functionality of the meter. An example of such a sensor is the already mentioned IR sensor of a thermal imaging camera, but there are also other sensors, which define an optical or acoustic recording axis, known and usable due to their measuring principle. In this description, the terms radial, axial, circumferential direction, etc. are used with respect to this receiving axis.

In one embodiment of the invention can be provided that on the receiving frame a nozzle is formed, which receives a sensor associated with the receiving optics. Preferably, the neck is tubular in shape to receive the receiving optics. The advantage here is that a nozzle is a simple means to define a recording axis.

In one embodiment of the invention can be provided that a sighting device is attached to the receiving frame. Preferably, the sighting device is rigidly secured to the receiving frame. The advantage here is that a defined orientation of the sighting device can be set to a receiving axis of the sensor on the receiving frame. With the damping element according to the invention is avoidable that this orientation of the sighting device with respect to the receiving axis changed by mechanical shocks from the outside.

Alternatively or additionally, it may be provided that a visual camera is attached to the receiving frame. Preferably, the visual camera is rigidly attached to the receiving frame. The use of a visual camera is particularly advantageous if the sensor is set up to record measured values in a non-visible spectral range or other non-visible physical properties. An example of this is the already mentioned IR sensor or an acoustic sensor. The attachment of the visual camera to the receiving frame has the advantage that the orientation of the visual camera with respect to a receiving axis of the sensor against mechanical shock is estimated, since the damping acts on the receiving frame as a whole with the structures.

It is particularly favorable if both a sighting device and a visual camera are fastened to the mounting frame. This is a visual check of one with the sensor detected spatial angle range allows, and the sighting device can be used to align the sensor to an examination object. The shock absorption protects the alignment of the sensor, the sighting device and the visual camera.

In one embodiment of the invention can be provided that the at least one damping element is formed annularly with an opening, wherein one, in particular the already mentioned, receiving axis of the sensor is guided through the opening. The advantage here is that with respect to the receiving axis radially all-sided damping of the receiving frame can be achieved. Thus, the receiving frame against all radially with respect to the receiving axis or laterally acting shocks can be estimated.

Alternatively or additionally, it may be provided that the at least one damping element is formed annularly with an opening, wherein a, in particular the previously mentioned, nozzle of the receiving frame is arranged in the opening. The advantage here is that a receiving optics in the neck along a circumference of the neck can be damped on all sides to the outside.

In one embodiment of the invention can be provided that at least two damping elements spaced from each other are arranged on the receiving frame. Preferably, the damping elements are annular and / or axially spaced from each other. The advantage here is that the damping elements spaced from each other act on the receiving frame, whereby a position or orientation of the receiving frame defined in the measuring device can be predetermined. Further attachment points of the receiving frame in the housing are dispensable. The receiving frame can thus be arranged freely suspended in the housing otherwise. Thus, it can be achieved that the receiving frame can be decoupled against impact from the housing.

In one embodiment of the invention it can be provided that the at least one damping element is inserted between the receiving frame and a holding frame suspended in the housing. The advantage here is that defined points of attack for the damping element can be provided, via which the at least one damping element can be supported on the housing. Another advantage is that the support frame can provide additional protection for the sensor. Preferably, the holding frame forms an inner housing which receives the receiving frame with the sensor.

In one embodiment of the invention can be provided that the damping element is biased. The advantage here is that a mechanical play of the damping element on the receiving frame and / or a holding frame is avoidable, so that the occurrence of mechanical shocks, which could act on the receiving frame, is even better avoidable.

In one embodiment of the invention can be provided that on the receiving frame, a support surface is formed, on which rests the at least one damping element. The advantage here is that a stable support of the receiving frame is formed. Preferably, the support surface is formed radially with respect to a receiving axis of the sensor to accommodate radially directed shocks can. Alternatively or additionally, it can be provided that at least one bearing surface is formed on the or a holding frame, against which the at least one damping element rests. The advantage here is that defined support points are provided on the support frame, which is engaged by the damping element. Preferably, the at least one support surface on the support frame is radially oriented with respect to a receiving axis of the sensor to dampen radially aligned shocks.

In one embodiment of the invention can be provided that in the at least one bearing surface, a recess is formed, which encloses a cavity with the at least one damping element. The advantage here is that the cavity can be filled in a mechanical stress from the outside by a shock or the like with the gel material of the damping element. Thus, an escape space can be provided, in which the damping element can deform during the damping process. The described cavity can in this case be formed on the support surface of the receiving frame and / or the holding frame.

In one embodiment of the invention can be provided that on the receiving frame and / or one, for example, the already mentioned, holding frame an axially oriented contact surface is formed, on which the damping element is axially fixed at least on one side. The advantage here is that axially aligned with respect to a receiving axis of the sensor shocks are damped with the damping element.

In one embodiment of the invention can be provided that the at least one damping element is positively fixed to the receiving frame and / or a, for example, the already described, holding frame against rotation about the receiving direction. The advantage here is that even a mechanical stress, which causes a distortion of the housing against the receiving frame about a receiving axis of the sensor, can be damped.

As a result of the combination of radially oriented contact surfaces, axially oriented contact surfaces and the described positive connection, damping acting on all sides in all spatial directions and a defined positioning of the receiving frame can thus be achieved.

In one embodiment of the invention, it can be provided that at least one elastic element is inserted between the housing and a, for example, the already mentioned, holding frame. The advantage here is that a mechanical decoupling between the housing and the receiving frame is further improved by a two-stage decoupling can be formed. The first stage here is elastic, while the second stage - formed by the damping element according to the invention - has increased damping properties. For example, the elastic element may be formed from a thermoplastic elastomer. The combination of an elastic element with a damping element connected downstream in the force path has proved to be particularly favorable in order largely to avoid interference of the sensor attached to the receiving frame by impacts and the like from the outside.

In one embodiment of the invention, it may be provided that a holding frame, for example the holding frame already described or a holding frame, on which the damping element engages to align the receiving frame, at least partially or completely made of magnesium, or magnesium, for example in an alloy contains , The advantage here is that a robust support frame is available, which has a low weight. To protect the sensor, the holding frame can surround the receiving frame in the form of a dish, at least half-way or even completely.

In one embodiment of the invention can be provided that the gel material is polyurethane gel. The advantage here is that good damping properties can be achieved.

In one embodiment of the invention can be provided that the gel material is provided with a cover layer. The advantage here is that a sticky consistency of the gel material can be covered. This facilitates the mounting of the damping element on the receiving frame and in the holding frame. For example, this cover layer may be formed by a coating of the gel material or by thermoforming foil.

In one embodiment of the invention it can be provided that a first board connected to the sensor is electrically connected to a second board connected to at least one operating element and / or a display unit via a flexible connecting line. The advantage here is that the second board is fixable to the housing, wherein operating commands and measurement data via the flexible connection line can be transferred and the sensor remains mechanically decoupled from the housing.

In one embodiment of the invention can be provided that the receiving frame is designed as a heat sink for the sensor. The advantage here is that the receiving frame can fill an additional function, whereby the number of parts of the measuring device can be reduced. The training as a heat sink is particularly advantageous if the sensor is a significant source of heat during operation. This is the case, for example, with the already mentioned IR sensors. The use of a heat sink as a receiving frame according to the invention has the further advantage that the heat sink is made due to their function of solid material and therefore provides a good mechanical stability. The heat sink is preferably made of metal.

In one embodiment of the invention can be provided that the meter is designed as a thermal imaging camera, with the sensor heat radiation is measurable. The advantage here is that the invention can be used in a range of measuring devices, in which the sensor technology requires increased production costs. With the invention, the life of such measuring devices can be extended, which is particularly favorable at high production costs.

The invention will now be described in detail with reference to an embodiment, but is not limited to this embodiment. Further exemplary embodiments result from a combination of the features of one or more claims with one another and / or with one or more features of the exemplary embodiment.

It shows:

1 FIG. 2 is a sectional view of a part of a measuring device according to the invention;

2 a three-dimensional oblique view of the meter according to 1 with removed mounting frame and retaining frame,

3 : a frontal view of the frame of the meter 1 .

4 a side view of the receiving frame according to 3 and

5 : an exploded view of the elements, about which the receiving frame to the support frame at the meter according to 1 is attached.

The 1 to 5 will be described together below.

Shown is a whole with 1 designated measuring device. The measuring device 1 is in a conventional manner as a handheld device with a handle 2 educated. The measuring device 1 is exemplified as a thermal imaging camera to illustrate the invention. The invention can also be used with other measuring devices with impact-sensitive sensors.

The measuring device 1 has a housing 3 inside, inside of which a picture frame 4 is trained.

The recording frame 4 serves to accommodate the sensor 5 , In the described embodiment, the sensor 5 designed as an IR sensor in a conventional manner. In other embodiments, sensor types are other than sensor 5 realized.

The sensor 5 is on the recording frame 4 fixed so that a desired orientation of the sensor 5 in terms of the geometry of the mounting frame 4 is set up.

The location and orientation of the mounting frame 4 in the case 3 is by a first damping element 6 specified. The recording frame 4 is thus on the damping element 6 in the case 3 held.

The damping element 6 is made of a gel material. In the exemplary embodiment, this gel material is a polyurethane gel. Other embodiments may also utilize other gel materials, for example, urethane gel, silicone gel, ethylene gum, viscoelastic polymer materials, or silicone-free damping gels or the like.

In 1 it can be seen that the sensor 5 a recording axis 7 Are defined. This is in a tubular nozzle 8th a recording optics 9 arranged.

On the recording frame 4 are a sighting device 10 and a visual camera 11 rigidly attached. The sighting device 10 is designed here as a laser pointer.

The sighting device 10 and the visual camera 11 are thus rigid with respect to the receiving axis 7 of the sensor 5 and the recording optics 9 aligned.

In 5 it can be seen that the damping element 6 is annular, and an opening 12 encloses, through which the neck 8th is plugged.

This ensures that the recording axis 7 through the opening 12 runs.

The damping element 6 thus engages in the circumferential direction with respect to the receiving axis 7 on all sides radially to the receiving frame 4 and wear this.

Axial with respect to the receiving axis 7 spaced from the damping element 6 is a second damping element 13 arranged.

The damping element 13 is also annular with an opening 14 educated. In the opening 14 is the neck 8th of the recording frame 4 introduced so that the recording axis 7 also through the opening 14 runs.

The recording frame 4 is about the damping elements 6 and 13 in the case 3 kept and otherwise levitating in the housing 3 arranged.

This is in the case 3 a support frame 15 suspended from magnesium or a magnesium alloy. The support frame 15 surrounds the picture frame 4 cup-shaped half-sided and thus forms an inner casing, cf. 2 ,

The damping elements 6 . 13 are between the support frame 15 and the recording frame 4 used.

At the neck 8th of the recording frame 4 is on the outside a radially oriented, the receiving axis 7 circumferential bearing surface 16 formed, on which the damping element 6 rests.

At the neck 8th is also a likewise radially oriented and also circumferential bearing surface 17 formed, on which the damping element 13 rests.

Through the bearing surfaces 16 . 17 becomes the recording frame 4 radially with respect to the receiving axis 7 on the damping elements 6 . 13 supported.

The support frame 15 has a stop ring 18 on which the damping elements 6 . 13 holds.

At the stop ring 18 are also radially oriented bearing surfaces 19 . 20 formed, via which the first damping element 6 or the second damping element 13 are supported radially.

In the sectional view according to 1 it can be seen that in the bearing surfaces 19 . 20 of the holding frame 15 in each case an annular circumferential recess 21 respectively. 22 is trained. Through the groove-shaped, annular recess 21 encloses the support surface 19 with the first damping element 6 an annular circumferential cavity 23 ,

Through the annular, groove-shaped circumferential recess 22 encloses the support surface 20 with the inserted second damping element 13 a likewise annular cavity 24 ,

The cavities 23 . 24 take in the case of a shock from outside the deforming during the damping process material of the damping elements 6 . 13 on.

In 5 is shown in the bearing surface 16 also an annular circumferential groove-shaped recess 25 is trained. Thus, the bearing surface forms 16 with the damping element 6 a further annular cavity (not shown).

In 5 It can also be seen that in the bearing surface 17 for the damping element 13 also an annular circumferential, groove-shaped recess 26 is trained. This recess 26 makes room for a cavity, also not shown between the support surface 17 and the damping element 13 ,

The two cavities of the recesses 25 . 26 also serve to accommodate the deforming damping elements 6 . 13 ,

The recesses 21 . 22 . 25 . 26 may also be formed with other geometric shapes to provide a suitable receiving space for the deforming gel material.

In 5 It can also be seen that on the neck 8th axially extending webs 27 are formed.

Corresponding to this are on the first damping element 6 and on the second damping element 13 axially extending grooves 28 formed, in which the webs 27 intervention.

In this way, the damping element 6 and the damping element 13 positively on the receiving frame 4 set and against rotation about the recording axis 7 secured.

At the damping elements 6 . 13 are also radially outwardly projecting corners 29 formed, which form-fitting with the bearing surfaces 19 . 20 cooperate such that a rotation of the damping elements 6 . 13 around the recording axis 7 relative to the support frame 15 with his stop ring 18 is prevented.

The corners 29 cause a corresponding positive connection between the damping element 6 respectively. 13 and the stop ring 18 ,

On the neck 8th are a stop ring 30 and a stop ring 31 attached, which each have an axially oriented contact surface 32 respectively. 33 provide.

At the annular circumferential contact surface 32 is the damping element 6 axially fixed on one side.

At the annular circumferential contact surface 33 is the damping element 13 axially fixed on one side after the opposite direction.

Thus, by combining the contact surfaces 32 . 33 with the damping elements 6 . 13 the recording frame 4 axially on both sides of the damping elements 6 . 13 established.

The stop rings 30 . 31 are positively locked against rotation on the socket 8th established. For this the web accesses 27 in a recess 44 ,

At the stop ring 18 of the holding frame 15 are also two annular circumferential contact surfaces 34 . 35 formed, which the damping elements 6 . 13 axially on both sides with respect to the support frame 15 establish.

Thus, the frame is 4 axially on both sides opposite the support frame 15 established.

On the neck 8th also becomes a bolting ring 36 screwed on which the damping elements 6 . 7 over the stop rings 30 . 31 put under pretension, so that the stop ring 18 and the neck 8th through the damping elements 6 . 13 are contacted without play.

In 5 is also apparent that the stop rings 30 . 31 are formed out of round.

The stop rings 30 . 31 thus cause on its respective outer side or on its respective circumference another positive connection between the damping elements 6 . 13 on the one hand and the recording frame on the other 4 on the other hand, which a rotation of the receiving frame 4 relative to the damping elements 6 . 13 around the recording axis 7 prevented.

Between the holding frame 15 and the housing 3 are elastic elements 37 used, through which the holding frame 15 in the case 3 held and aligned.

It should be mentioned that the damping elements 6 . 13 on the outside with a cover layer 38 provided to cover the sticky consistency of the gel material.

This topcoat 38 is made for example by painting or by surface treatment or as thermoforming film.

The sensor 5 is on a first board 39 arranged.

The measuring device 1 has controls 40 on, on the support frame 15 are arranged.

These controls 40 are on a second board 41 arranged and electrically contacted.

To the recording frame 4 mechanically from the support frame 15 to decouple, are the first board 39 and the second board 41 via a flexible connection line 40 electrically connected to each other.

On the holding frame 15 is also a display unit 43 for displaying measurement results of the sensor 5 and for displaying images of the visual camera 11 arranged. The second board 41 also contacts the display unit 43 and is firmly connected to it. The connection line 42 also serves to transfer the recorded images of the visual camera 11 ,

The sighting device 10 is about the controls 40 controllable. The transmission of the control commands also takes place via the connection line 42 ,

In the described embodiment, the receiving frame 4 designed as a solid metal body and acts as a heat sink for the sensor 5 ,

As already mentioned, the measuring device is in the described embodiment 1 designed as a thermal imaging camera, and the sensor 5 Measures heat radiation as an IR sensor. In further embodiments, the meter is 1 set up to measure another physical effect.

At the meter 1 with a shock-sensitive sensor 5 is proposed, at least one damping element 6 . 13 from a gel material between one the sensor 5 carrying frames 4 and a housing 3 of the meter 1 insert into an interior of the housing to provide shock absorption to the sensor 5 to build.

Claims (13)

Measuring device ( 1 ) with a housing ( 3 ) and one in the housing ( 3 ) ( 4 ), wherein on the receiving frame ( 4 ) a sensor ( 5 ) of the measuring device ( 1 ), characterized in that the receiving frame ( 4 ) via at least one damping element ( 6 . 13 ) of a gel material in the housing ( 3 ) is held. Measuring device ( 1 ) according to claim 1, characterized in that the sensor ( 5 ) on the frame ( 4 ) is fixed. Measuring device ( 1 ) according to claim 1 or 2, characterized in that the sensor ( 5 ) an optical or acoustic recording axis ( 7 ) and / or that on the frame ( 4 ) a preferably tubular neck ( 8th ) is formed, which one the sensor ( 5 ) associated recording optics ( 9 ). Measuring device ( 1 ) according to one of claims 1 to 3, characterized in that a sighting device ( 10 ) and / or a visual camera ( 11 ) on the frame ( 14 ), preferably rigidly attached, is / are. Measuring device ( 1 ) according to one of claims 1 to 4, characterized in that the at least one damping element ( 6 . 13 ) annular with an opening ( 12 . 14 ), wherein the or a receiving axis ( 7 ) of the sensor ( 5 ) through the opening ( 12 . 14 ) and / or the or a nozzle ( 8th ) of the frame ( 4 ) in the opening ( 12 . 14 ) is arranged. Measuring device ( 1 ) according to one of claims 1 to 5, characterized in that at least two preferably annular design damping elements ( 6 . 13 ) spaced from each other, in particular axially spaced from each other, on the receiving frame ( 4 ) are arranged. Measuring device ( 1 ) according to one of claims 1 to 6, characterized in that the at least one damping element ( 6 . 13 ) between the frame of admission ( 4 ) and one in the housing ( 3 ) suspended support frame ( 15 ) is inserted and / or that the at least one damping element ( 6 . 13 ) is subjected to a bias voltage. Measuring device ( 1 ) according to one of claims 1 to 7, characterized in that on the receiving frame ( 4 ) and / or on the or a support frame ( 15 ) at least one preferably radially oriented bearing surface ( 16 . 17 . 19 . 20 ) is formed, on which the at least one damping element ( 6 . 13 ) rests, and / or that in the at least one bearing surface ( 16 . 17 . 19 . 20 ) a recess ( 21 . 22 . 25 . 26 ) is formed, which with the at least one damping element ( 6 . 13 ) a cavity ( 23 . 24 ) encloses. Measuring device ( 1 ) according to one of claims 1 to 8, characterized in that on the receiving frame ( 4 ) and / or the or a holding frame ( 15 ) an axially oriented contact surface ( 32 . 33 . 34 . 35 ) is formed, on which the damping element ( 6 . 13 ) is axially fixed at least on one side, and / or that the at least one damping element ( 6 . 13 ) in a form-fitting manner on the receiving frame ( 4 ) and / or the or a holding frame ( 15 ) against rotation about the receiving axis ( 7 ). Measuring device ( 1 ) according to one of claims 1 to 9, characterized in that between the housing ( 3 ) and the or a support frame ( 15 ) at least one elastic element ( 37 ), in particular of a thermoplastic elastomer, is inserted. Measuring device ( 1 ) according to one of claims 1 to 10, characterized in that the or a holding frame ( 4 ) is at least partially made of magnesium or contains magnesium and / or that the gel material polyurethane gel and / or with a cover layer ( 38 ) is provided. Measuring device ( 1 ) according to one of claims 1 to 11, characterized in that a to the sensor ( 5 ) connected first board ( 39 ) with one with at least one operating element ( 40 ) and / or a display unit ( 43 ) connected second board ( 41 ) via a flexible connection line ( 42 ) is electrically connected. Measuring device ( 1 ) according to one of claims 1 to 12, characterized in that the receiving frame ( 4 ) as a heat sink for the sensor ( 5 ) and / or that the measuring device ( 1 ) is designed as a thermal imaging camera, wherein with the sensor ( 5 ) Heat radiation is measurable.

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