DE202016100168U1 - Lever with a seismic reflection foil - Google Patents

Abstract

A lever comprising a seismic reflective sheet, comprising: a base (1); a lever plate (2), wherein a first shaft assembly (21) and a second shaft assembly (22) on the lever plate (2) are arranged, wherein the first shaft assembly (21) includes a first spring (211) and a first shaft (212), wherein the first spring (211) is slid onto the first shaft (212), the first shaft being disposed on one side of the lever plate (2) and the base (1), the first spring (211) being interposed between the base (1 ) and the lever plate (2) and comes into contact with the base (1) to produce an elastic torque for the rotation, a reflection foil (3), the second wave structure (22) being arranged between a bottom side of the reflection foil (3 ) and another end of the lever plate (2) are arranged.

Description

BACKGROUND OF THE INVENTION

a) Field of the invention

The present invention relates to a lever with a seismic reflection sheet, in particular a seismic reflection sheet, which is used on a head-up display in vehicles, with the operation of the lever improves their seismic capacity and this is not affected by vibrations of the dashboard in the vehicle , whereby the attachment and the carrying stability of the reflection foil are improved.

b) State of the art

In a vehicle, access to multiple information becomes increasingly easier, but there is a high risk of accident if the driver does not pay attention to the road when reading the information. To overcome these disadvantages, head-up displays have been developed so that the driver can read the information without having to divert his attention from the road. In particular, the head-up displays are shaped as a concave mirror for imaging, wherein the display area can be increased and the distance between the displayed image and the eyes of the driver is large enough, usually greater than 2 meters. When the driver sees the displayed information, the focal length of the eyes is close to the line of sight of the driver so that the driver can continue to focus his attention on the road while reading the information so that driving safety is not jeopardized.

The virtual image is created with a concave mirror, where the imaging formula (of the concave mirror) is 1 / p + 1 / q = 1 / f, where f is the aperture, q is the object distance, and p is the image distance. The virtual images can be magnified with a general magnification, wherein the distance of the virtual image in the same ratio for best readability can be at the same time between four to six times as large. If the magnification is too strong, this can cause a dizziness in the reader, so that the distance between the virtual image and the eye of the driver may be greater than 2 meters, with the image at the rear of the reflective film with a distance of more than 1.2 Meters, ie the distance of the optical path from the display to the concave mirror may be greater than 24 cm (if the magnification is five times larger). In addition, the distance of the optical path can be increased by backward and forward reflection through a mirror surface, wherein the circumference required by the optical path is large, so that the receiving space for the head-up display device is usually formed within the dashboard.

This method can only be applied if the original manufacturer already takes into account the desired recording space during the planning period. When installed, the head-up display can not be mounted on the dashboard because the head-up display with the optical path device is too large and may even obstruct the driver's line of sight.

Another solution for the optical path device, which is of considerable size, is the separate installation of this device with the display mounted on top of the windshield and the reflective foil on the dashboard. The dashboard is subject to vibration in most vehicles because of the rotation of the engine or compressor of the air conditioner, which can shake the reflective film attached above. The magnification effect of the concave mirror enhances the shift of the displayed image due to the vibration, causing the displayed image to vibrate strongly.

In order to solve the problem with respect to the vibrations of the reflection foil, the inventor of the present invention has patent applications TW 530961 . TW M273183 . TW M375372 . TW 576080 . TW I352165 . TW M288937 . TW M275639 etc., and has found that the technical contents and applications disclosed therein continue to suffer from technical drawbacks which cause a problem due to vibrations of the reflection foil according to the known embodiment.

Although the reflection foil can be tightly and firmly attached to the windshield by utilizing the elasticity of an elastic member to withstand the inertia of the vibration, the effect achieved thereby to solve the problem of the vibration of the reflection foil is limited. The elasticity of the elastic element remains unchanged, the moment of inertia of the vibrations in various strengths is dynamic, so that the problem of vibration can be eliminated if the elasticity of the elastic element is greater than the maximum moment of inertia of the vibrations. However, if no vibrations are present, the elasticity of the elastic element leads to deformations of the reflection foil, so that this method is not a good solution.

SUMMARY OF THE INVENTION

In order to solve the above-mentioned problems, the inventor has, after numerous developments, finally provided a lever with a seismic reflection sheet according to the present invention, the object of the present invention thus being to provide a reflection sheet in which the seismic capacity is leveraged is improved, without affecting the reflective film by the vibrations of the dashboard in the vehicle, whereby the attachment and the carrying stability of the reflective film can be improved.

To achieve this effect, the first embodiment of the seismic reflection sheet lever according to the present invention includes the following elements:
One Base,
a lever plate, a first shaft assembly and a second shaft assembly, which are arranged on the lever plate, wherein the first shaft assembly consists of a first spring and a first shaft, wherein the first spring is pushed onto the first shaft, wherein the first shaft on one side of the Lever plate and the base is arranged, wherein the first spring between the base and the lever plate is arranged and comes into contact with these, in order to generate a resilient torque for rotation,
a reflective foil, wherein the second wave structure is arranged between an underside of the reflective foil and another end of the lever plate.

The base further includes a footplate disposed on an underside of the base, wherein a double-sided adhesive strip is provided under the footplate for attachment to a dashboard.

On the upper side of the reflective sheet, a cushioning block is disposed, which cushioning block comes into contact with a windshield to reduce the vibration of the reflective sheet.

The second shaft construction is made as a hinge.

The second shaft assembly includes a second spring and a second shaft.

The lever with a seismic reflective sheet according to the present invention further includes an angle adjusting mechanism including a support block and an angle adjusting rod and having an adjusting hole, the supporting block being disposed at one end of a lower side of the lever plate, the adjusting hole being formed in the reflecting sheet, the angle adjusting rod being rotatable may be provided in the adjustment hole, wherein the length of the part, which is moved over the adjustment hole and comes into contact with the support block, is used for forming a tilt angle of the reflection film for a limited adjustment.

The reflection film is formed as a slightly clouded and semi-reflective, concave mirror.

The second embodiment of a lever according to the invention with a seismic reflection foil comprises the following elements:
One Base,
a lever plate, wherein a first shaft assembly and a second shaft assembly are arranged on the lever plate, wherein the first shaft assembly includes a spring and a first shaft, wherein the first spring is pushed onto the first shaft, wherein the first shaft on one side of the lever plate and the base is arranged
a counterweight disposed at one end of the lever plate,
a reflective sheet, wherein the second wave structure is disposed between an underside of the reflective sheet and another end of the lever sheet.

An engaging member is disposed at one end of the lever plate for fixing the reflection foil.

The base also includes a footplate disposed on an underside of the base, with a double-sided adhesive strip at the bottom of the footplate for attachment to a dashboard.

On the upper side of the reflective sheet, a cushioning block is disposed, which cushioning block comes into contact with a windshield to reduce the vibration of the reflective sheet.

The second shaft construction is made as a hinge.

The second shaft assembly further includes a second spring and a second shaft.

The lever with a seismic reflective sheet further includes an angle adjustment mechanism comprising a support block and an angle adjustment rod and having an adjustment hole, wherein the support block is disposed at one end of a lower side of the lever plate, wherein the adjustment hole is formed in the reflection foil, wherein the Winkelverstellstange rotatably in can be added to the adjustment hole, with the length of the Part, which is moved over the adjustment hole and which comes into contact with the support block, a tilt angle of the reflection foil is formed, which is used for a limited adjustment.

The reflection film is formed as a slightly clouded and semi-reflective, concave mirror.

BRIEF DESCRIPTION OF THE DRAWINGS

1 shows a three-dimensional exploded view of the first embodiment of the present invention,

2 shows a three-dimensional view of the first embodiment of the present invention,

3 shows a cross-sectional view of the first embodiment of the present invention,

4 FIG. 12 is a schematic view showing another example of the second shaft structure of the first embodiment of the present invention; FIG.

5 shows a schematic view of the movement of the second embodiment of the present invention, and

6 Fig. 12 is a schematic view showing another example of the second shaft structure of the second embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The 1 . 2 . 3 represent the first embodiment of the lever according to the invention with a seismic reflection film with a base 1 , a lever plate 2 and a reflective sheet 3 represents.

At the base 1 are two corresponding first arms 11 shaped, with in each of these first arms 11 a first shaft hole 111 are formed.

A second wave hole 201 is on one side of the lever plate 2 formed while on the other side of the lever plate 2 two second arms 202 are shaped. A third hole 203 is in the second arm 202 educated. A first wave structure 21 and a second wave structure 22 are at the lever plate 2 formed, with the first wave structure 21 a first spring 211 and a first wave 212 includes. The first spring 211 is on the first wave 212 deferred, with the first wave 212 in the second shaft hole 201 on one side of the lever plate 2 and in the first wave hole 111 the base 1 is introduced. Two pens 213 . 214 the first spring 211 are between the base 1 and the lever plate 2 arranged to come into contact with these to produce an elastic torque for rotation, wherein for the first spring 211 a torsion spring is used.

The reflection foil 3 is formed as a slightly clouded and semi-reflective concave mirror, whereby a virtual image can be magnified by the concave image and the virtual image can also be displayed at a greater distance. A clamping piece 301 in which several first through holes 302 are formed, is at the bottom of the reflective film 3 arranged, with this clamping piece 301 a tiltable block 31 at the bottom of the reflective foil 3 is attached. The tilting block 31 includes a front jaw 311 and a rear jaw 312 , From one side of the rear jaw 312 is a flange 313 out. A fourth wave hole 314 is in the flange part 313 formed, wherein the second wave structure 22 is formed as a hinge, through the third shaft hole 203 at the other end of the lever plate 2 sticks out while a fourth shaft hole 314 of the tiltable block 31 at the bottom of the reflective foil 3 is trained. With the elastic torque caused by the vibration of the first spring 221 is generated, between the lever plate 2 and the tiltable block 31 generates a moment of leverage, causing the reflective foil 3 can be pressed against a windshield W, whereby the attachment and the carrying stability of the reflection foil can be improved. If no vibration occurs, may be from the first spring 211 no elastic force on the reflective foil 3 be exercised, thereby causing a deformation of the reflective film 3 can be effectively prevented.

The second wave structure 22 includes a second wave 222 where a locking screw as the second shaft 222 is used and this locking screw when adjusting the angle between the reflective foil 3 and the lever plate 2 can be attracted.

At the rear jaw 312 of the tiltable block 31 are several second through holes 315 formed, these second through holes 315 with an internal thread 316 on the front jaw 311 to match. The first through holes 302 are for a screw 317 shaped continuously, with the screw 317 in this is attached to the tilting block 31 at the bottom of the reflective foil 3 to fix.

The base 1 also has a foot plate 4 on that at a base of the base 1 is arranged, with a double-sided adhesive strip 41 at the bottom of the foot plate 4 is intended to adhere to a dashboard B.

At the top of the reflective foil 3 is a damping block 32 arranged, which is made of a soft material. The damping block 32 is on an upper side 303 the reflection foil 3 attached. The damping block 32 is pressed against the windshield W to the vibrations of the reflective foil 3 to reduce.

The 4 shows another example of the second wave structure 22 , wherein this second wave structure 22 a second spring 221 and a second wave 222 includes. The second spring 221 is on the second wave 222 deferred, the second wave 222 through the third shaft hole 203 in one end of the lever plate 2 and through the fourth wave hole 314 in the tiltable block 31 at the bottom of the reflective foil 3 protrudes. Two pens 223 . 224 the second spring 221 come with the lever plate 2 and the tiltable block 31 the reflection foil 3 are arranged between them to generate an elastic torque for the rotation and the seismic function of the reflection foil 3 improve as a second spring 221 a torsion spring is used.

The 4 shows that the lever according to the invention with a seismic reflection foil also a Winkelverstellmechanismus 5 and this angle adjustment mechanism 5 a support block 51 and an angle adjustment rod 52 includes and an adjustment hole 53 having. The support block 51 is at one end of a bottom of the lever plate 2 arranged and the adjustment hole 53 is in the reflective foil 3 educated. The angle adjustment rod 52 can rotate in the adjustment hole 53 be included. With the length of the part, that over the adjustment hole 53 protrudes and with the support block 51 comes into contact, a tilt angle of the reflective film 3 formed for a limited adjustment. Next, the reflective foil 3 with the elastic moment, that with the second spring 221 is generated, tilted, with the Winkelverstellmechanismus 5 the angle is adjusted and the reflective foil 3 can be fixed, so that an adjustment of the angle by the user when tilting the reflective foil 3 can be avoided.

The second embodiment of the lever according to the invention with a seismic reflection foil (see 1 and 5 ) includes a base 1 , a lever plate 2 , a counterweight 23 and a reflective sheet 3 ,

At the base 1 are two corresponding first arms 11 shaped while a first shaft hole 111 in every first arm 11 is trained.

On one side of the lever plate 2 is a second shaft hole 201 formed, with two corresponding second arms 202 on another side of the lever plate 2 are formed and a third hole 203 in the second arm 202 is shaped. A first wave structure 21 and a second wave structure 22 are at the lever plate 2 arranged, with the first wave structure 21 a first spring 211 and a first wave 212 includes. The first spring 211 is on the first wave 212 postponed. The first wave 212 is in the second shaft hole 201 on one side of the lever plate 2 and in the first wave hole 111 in the base 1 inserted. Two pens 213 . 214 the first spring 211 are between the base 1 and the lever plate 2 arranged to come into contact with these to produce an elastic torque for rotation, wherein as the first spring 211 a torsion spring is used.

At one end of the lever plate 2 a counterweight is arranged, with the best mounting position depending on the modulation weight and the position of the counterweight 23 is.

The reflection foil 3 is formed as a slightly clouded and semi-reflecting concave mirror, whereby a virtual image can be magnified by the concave mirror, and the virtual image can also be displayed at a greater distance. A clamping piece 301 is at the bottom of the reflective foil 3 arranged in which several first through holes 302 are formed, with the clamping piece 301 a tiltable block 31 at the bottom of the reflective foil 3 is attached. The tilting block 31 includes a front jaw 311 and a rear jaw 312 , A flange part 313 stands from one side of the rear jaw 312 out. A fourth wave hole 314 is in the flange part 313 formed, wherein the second wave structure 22 as a hinge formed by the third shaft hole 203 at the other end of the lever plate 2 sticks out while a fourth shaft hole 314 of the tiltable block 31 at the bottom of the reflective foil 3 is trained. With the elastic torque caused by the vibration of the first spring 221 is generated, between the lever plate 2 and the tiltable block 31 generates a moment of leverage, so that the reflective foil 3 to a windshield W can be pressed to improve the attachment and the carrying stability of the reflective film. If no vibration occurs, may be from the first spring 211 no elastic moment on the reflective foil 3 be exercised, causing a deformation of the reflective film 3 can be effectively prevented.

The second wave structure 22 includes a second wave 222 where a locking screw as the second shaft 222 is used and this locking screw when adjusting the angle between the reflective foil 3 and the lever plate 2 can be attracted.

At the rear jaw 312 of the tiltable block 31 are several second through holes 315 formed, these second through holes 315 with an internal thread 316 on the front jaw 311 to match. The first through holes 302 are for a screw 317 shaped continuously, with the screw 317 in this is attached to the tilting block 31 at the bottom of the reflective foil 3 to fix.

The base 1 also includes a footplate 4 attached to a base of the base 1 is arranged, with a double-sided adhesive strip 41 at the bottom of the foot plate 4 is intended for attachment to a dashboard B.

At the top of the reflective foil 3 is a damping block 32 arranged, which is made of a soft material. The damping block 32 is on an upper side 303 the reflection foil 3 attached. The damping block 32 is pressed against the windshield W to the vibrations of the reflective foil 3 to reduce.

The length of one end of the lever plate 2 The present invention may be selected depending on the usage requirements, wherein an engaging part 24 it is formed. The elasticity of the material of the engaging part 24 allows folding of the reflective foil 3 and attaching this reflective sheet 3 on the upper side of this engaging part 24 , wherein the reflection foil 3 unfolded when unfolded elastic / can escape.

The 6 shows that the lever according to the invention with a seismic reflection foil also a Winkelverstellmechanismus 5 and this angle adjustment mechanism 5 a support block 51 and an angle adjustment rod 52 includes and an adjustment hole 53 having. The support block 51 is at one end of a bottom of the lever plate 2 arranged and the adjustment hole 53 is in the reflective foil 3 educated. The angle adjustment rod 52 can rotate in the adjustment hole 53 be included. With the length of the part of the angle adjustment rod 52 , which from the adjustment hole 53 protrudes and with the support block 51 comes into contact, a tilt angle of the reflective film 3 formed for a limited adjustment. Next, the reflective foil 3 with the moment, that with the second spring 221 is generated, tilted, with the Winkelverstellmechanismus 5 the angle is adjusted and the reflective foil 3 can be fixed, so that an adjustment of the angle by the user when tilting the reflective foil 3 is prevented.

The 6 shows another example of the second wave structure 22 , wherein the second wave structure 22 a second spring 221 and a second wave 222 includes. The second spring 221 is on the second wave 22 postponed. The second wave 222 protrudes through the third shaft hole 203 in one end of the lever plate 2 and into the fourth wave hole 314 of the tiltable block 31 at the bottom of the reflective foil 3 , Two pens 223 . 224 the second spring 221 come with the lever plate 2 and the tiltable block 31 the reflection foil 3 In order to generate an elastic torque for the rotation, the seismic function of the reflection foil 3 improve as a second spring 221 a torsion spring is used.

From the embodiments described above, it is apparent that in the present invention, an elastic torque by the first spring 211 and the second spring 221 is generated to the reflective film 3 with the lever plate 2 used as a rotation center of the lever to press against the windshield W. In addition, in addition, a counterweight 23 at one end of the lever plate 2 whose torque is greater than the torque of another end of the reflective foil 3 (Torque = distance to gravity × weight) is. When jolting while driving on the road, all objects are caused to vibrate due to inertia, so that a downward force on the reflective foil 3 and with the counterweight 23 a downward force is applied to another end. If the center of the lever is fixed, the torque of the counterweight 23 larger, with the downward force on the reflective foil 3 can be compensated and an excess upward force is generated. The center of the lever is mounted on the dashboard B, with the material of the instrument panel B normally being soft to some degree, having a weight and therefore also experiencing a downward force, so that the downward force on the counterweight 23 must be greater by the amount of downward forces on the center of the lever and the reflective foil 3 compensate. Therefore, with the structure of the invention, by applying the lever operation, the problem of excessive vibration of the reflective sheet according to the known embodiment can be effectively solved to improve the seismic function.

In summary, the present invention relates to a lever with a seismic reflection foil having a base 1 , a lever plate 2 and a reflective sheet 3 includes. With an elastic torque of a first spring 211 becomes the reflective foil 3 pressed against the windshield W, wherein the lever plate acts as a center of rotation of the lever, so that the reflective film 3 is not affected by the vibrations of the dashboard B in the vehicle, in this way the attachment and the carrying stability of the reflective foil 3 to improve.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• TW 530961 [0006]
• TW 273183 [0006]
• TW 375372 [0006]
• TW 576080 [0006]
• TW 352165 [0006]
• TW 288937 [0006]
• TW 275639 [0006]

Claims (15)

A seismic reflective film lever comprising: a base ( 1 ); a lever plate ( 2 ), wherein a first wave structure ( 21 ) and a second wave structure ( 22 ) on the lever plate ( 2 ) are arranged, wherein the first wave structure ( 21 ) a first spring ( 211 ) and a first wave ( 212 ), wherein the first spring ( 211 ) on the first wave ( 212 ), wherein the first shaft on one side of the lever plate ( 2 ) and the base ( 1 ) is arranged, wherein the first spring ( 211 ) between the base ( 1 ) and the lever plate ( 2 ) and with the base ( 1 ) comes into contact to produce an elastic torque for the rotation, a reflection foil ( 3 ), wherein the second wave structure ( 22 ) between a bottom of the reflective foil ( 3 ) and another end of the lever plate ( 2 ) are arranged. Lever with a seismic reflection sheet according to claim 1, wherein the base ( 1 ) further comprises a foot plate ( 4 ), which at an underside of the base ( 1 ), wherein a double-sided adhesive strip ( 41 ) at the bottom of the foot plate ( 4 ) is provided for attachment to a dashboard (B). Lever with a seismic reflection foil according to claim 1, wherein a damping block ( 32 ) on an upper side ( 303 ) of the reflection foil ( 3 ), wherein the attenuation block ( 32 ) is arranged so that it comes into contact with a windshield to the vibrations of the reflective foil ( 3 ) to reduce. Lever with a seismic reflection foil according to claim 1, wherein the second wave structure ( 22 ) is shaped as a hinge. Lever with a seismic reflection foil according to claim 1, wherein the second wave structure ( 22 ) a second spring ( 221 ) and a second wave ( 222 ). Lever with a seismic reflection foil according to claim 1, which also comprises an angle adjustment mechanism ( 5 ) having a support block ( 51 ), an angle adjustment rod ( 52 ) and an adjustment hole ( 53 ), wherein the support block ( 51 ) at one end of a lower side of the lever plate ( 2 ) is arranged, wherein the adjustment hole ( 53 ) in the reflection foil ( 3 ), wherein the angle adjustment rod ( 52 ) rotatable in the adjustment hole ( 53 ), wherein with the length of the part of the angle adjustment rod ( 52 ), which from the Justierloch ( 53 ) and with the support block ( 51 ), a tilt angle of the reflective foil ( 3 ), which is used for a limited adjustment. Lever with a seismic reflection foil according to claim 1, wherein the reflection foil ( 3 ) is formed as a slightly clouded and semi-reflective, concave mirror. A seismic reflective film lever comprising: a base ( 1 ); a lever plate ( 2 ), wherein a first wave structure ( 21 ) and a second wave structure ( 22 ) on the lever plate ( 2 ), wherein the first shaft structure ( 21 ) a first spring ( 211 ) and a first wave ( 212 ), wherein the first spring ( 211 ) on the first wave ( 212 ), the first wave ( 212 ) on one side of the lever plate ( 2 ) and the base ( 1 ), a counterweight ( 23 ) at one end of the lever plate ( 2 ), a reflection foil ( 3 ), wherein the second wave structure ( 22 ) between a bottom of the reflective foil ( 3 ) and another end of the lever plate ( 2 ) is arranged. Lever with a seismic reflection sheet according to claim 8, wherein an engagement part ( 24 ) at one end of the lever plate ( 2 ) for fixing the reflection foil ( 3 ) is trained. Lever with a seismic reflective sheet according to claim 8, wherein the base ( 1 ) further comprises a foot plate ( 4 ), wherein the foot plate ( 4 ) on an underside of the base ( 1 ), wherein a double-sided adhesive strip ( 41 ) at the bottom of the foot plate ( 4 ) is provided for attachment to a dashboard (B). Lever with a seismic reflection foil according to claim 8, wherein a damping block ( 32 ) on an upper side ( 303 ) of the reflection foil ( 3 ), wherein the attenuation block ( 32 ) is arranged so that it comes into contact with a windshield to the vibration of the reflective foil ( 3 ) to reduce. Lever with a seismic reflection foil according to claim 8, wherein the second wave structure ( 22 ) is made as a hinge. Lever with a seismic reflection foil according to claim 8, wherein the second wave structure ( 22 ) a second spring ( 221 ) and a second wave ( 222 ). Lever with a seismic reflection foil according to claim 8, which also has an angle adjustment mechanism ( 5 ) comprising a support block ( 51 ), an angle adjustment rod ( 52 ) and a Adjustment hole ( 53 ), wherein the support block ( 51 ) at one end of a lower side of the lever plate ( 2 ) is arranged, wherein the adjustment hole ( 53 ) in the reflection foil ( 3 ), the angle adjustment rod ( 52 ) rotatable in the adjustment hole ( 53 ), wherein with the length of the part of the angle adjustment rod ( 52 ), which via the adjustment hole ( 53 ) and with the support block ( 51 ), a tilt angle of the reflective foil ( 3 ), which is used for a limited adjustment. Lever with a seismic reflection foil according to claim 8, wherein the reflection foil ( 3 ) is formed as a slightly clouded and semi-reflective, concave mirror.

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