CN204990071U - Three-dimensional grasping adjustment structure and multi-dimensional adjustment device - Google Patents

Abstract

The utility model relates to a three-dimensional grabbing adjustment structure and a multi-dimensional adjustment device, wherein the three-dimensional grabbing adjustment structure comprises a grabbing adjustment unit and an adjustment unit; the multidimensional adjusting device comprises a three-dimensional grabbing adjusting structure, a connecting unit and a three-dimensional displacement adjusting structure, wherein one end of the connecting unit is connected with the three-dimensional grabbing adjusting structure, the other end of the connecting unit is connected with the three-dimensional displacement adjusting structure, and a projection module is clamped by a grabbing part of the three-dimensional grabbing adjusting structure, so that the image projected by the projection module can be adjusted in a multidimensional direction, and the effects of high adjusting precision and convenience in operation are effectively achieved.

Description

Three-dimensional grasping adjustment structure and multi-dimensional adjustment device

【Technical field】

The utility model relates to a multi-dimensional adjustment device, in particular to a three-dimensional grasping adjustment structure and a multi-dimensional adjustment device with high adjustment accuracy and convenient operation.

【Background technique】

As tablet computers become more and more popular in daily life, the touch operation of the touch panel becomes more and more frequent. In order to save weight and mechanical space, the tablet computer cancels the physical keyboard of the traditional notebook computer and replaces it with the physical keyboard on the display screen. Virtual keyboard instead. However, since the virtual keyboard in the display screen will occupy the screen space that hinders the display screen during input, the industry has developed a micro-projection module installed on a tablet computer that can project a virtual keyboard.

And the known tablet computer is respectively assembled a micro-projection module on the left and right sides of the front shell, so that the left and right micro-projection modules project the left half and the right half of the virtual keyboard respectively to achieve the projected The entire virtual keyboard, but after assembling the aforementioned left and right micro-projection modules on the tablet computer, the operator needs to adjust the virtual keyboard projected by the left and right micro-projection modules to correspond to a keyboard model in front, such as on the tablet computer. The left micro-projection module projected that the left half (or right half) of the virtual keyboard does not correspond to the left half (or right half) of the previous keyboard template, so that the assembler needs to manually ( Or use tweezers) to clamp the left micro-projection module (or right micro-projection module) on the tablet computer and rotate the projected virtual keyboard image to correspond to the keyboard template.

However, the above-mentioned known adjustment methods for the left and right micro-projection modules cannot be accurately matched to the keyboard model, because it is not easy to operate when adjusting the left and right micro-projection modules by manual rotation, such as the front of the tablet computer and the projection The small space between the virtual keyboards cannot be finely adjusted manually, so that it is easy to cause over-adjustment or under-adjustment, and the hands of the assembler are also likely to block the light projected on the virtual keyboard, resulting in adjustment errors and The problem of low adjustment accuracy is difficult to meet the requirements, and even more difficult to achieve mass production.

Therefore, how to solve the problems and deficiencies of the above-mentioned common usage is the direction that the utility modeler of this case and the relevant manufacturers engaged in this industry want to study and improve.

【Content of utility model】

In order to effectively solve the above problems, the main purpose of this utility model is to provide a three-dimensional grasping adjustment structure with high adjustment accuracy and convenient operation.

Another object of the present invention is to provide a multi-dimensional adjustment device with high adjustment accuracy and convenient operation.

Another object of the present invention is to provide a multi-dimensional adjustment device that can easily adjust a virtual keyboard projected by a projection module mounted on a tablet computer to effectively achieve the effect of mass production.

In order to achieve the above purpose, the utility model provides a three-dimensional grasping adjustment structure, which is applied to a corresponding projection module for adjustment. The three-dimensional grasping adjustment structure includes: a grasping adjustment unit, which has a grasping part, a first A port and a second port, the first port and the second port are opened on one end and the other end of the grasping adjustment unit respectively, the first port communicates with the second port, and the grasping part It is arranged on one end of the grasping adjustment unit adjacent to the first port; an adjustment unit has a first adjustment part, a second adjustment part and a fixing part, and the first adjustment part is accommodated in the first adjustment part The second adjustment part is accommodated in the fixed part and moves in a second direction, and the grasping adjustment unit is accommodated in the first adjustment unit and moves in a third direction; and wherein the first adjustment part moves in the second direction along with the second adjustment part, and the grasping adjustment unit moves in the first and second directions along with the first and second adjustment parts.

The gripping portion is provided with a convex wall and a plurality of convex posts, the convex wall is formed on one end of the gripping adjustment unit adjacent to the first port, and the convex posts grab from two opposite outer sides of the convex wall One end of the adjustment unit is formed by protruding outwards through the convex wall.

The grasping adjustment unit is provided with a movable part and a gradually expanding part, and the gradually expanding part is formed by gradually expanding outward from the movable part, and the second port is formed at the center of the gradually expanding part, and the movable part has A plurality of external threads are formed on the outer peripheral side of the movable part, and the first port is formed at the center of the movable part.

The first and second adjustment parts are respectively provided with a first hollow opening and a second hollow opening, the first and second hollow openings are respectively formed at the center of the first and second adjustment parts, and the inner periphery of the first hollow opening It has a plurality of internal threads, and the internal threads are screwed with the external threads corresponding to the movable part. The first adjustment part is accommodated in the second hollow opening, and its upper and lower sides are respectively connected with the corresponding second adjustment part. The upper and lower sides of the fixed part are provided with a third hollow opening for accommodating the second adjustment part, and the left and right sides of the fixed part are respectively corresponding to the left and right sides of the second adjustment part. Pivot.

The grasping part clamps the projection module, the projection module has a projection lens and a base, the projection lens is set on one side of the base, and it is sleeved in the first opening, and the protrusion Clips correspond to the perimeter sides of the base.

Through the design of the structure of the utility model, the effect of high adjustment precision and convenient operation can be effectively achieved.

The utility model further provides a multi-dimensional adjustment device, which is applied to adjust at least one projection module mounted on an electronic device. The multi-dimensional adjustment device includes:

A three-dimensional grasping adjustment structure, including:

A grasping adjustment unit has a grasping portion, a first port and a second port, the first and second ports are set on one end and the other end of the grasping adjustment unit respectively, the first port The mouth communicates with the second port, and the grasping portion is arranged on one end of the grasping adjustment unit adjacent to the first port;

An adjustment unit has a first adjustment part, a second adjustment part and a fixing part, the first adjustment part is accommodated in the second adjustment part and moves in a first direction, the second adjustment part is accommodated in the The fixing part is movable in a second direction, and the grasping adjustment unit is accommodated in the first adjustment unit and is movable in a third direction; and

Wherein the first adjustment part moves in the second direction along with the second adjustment part, and the grasping adjustment unit moves in the first and second directions along with the first and second adjustment parts;

a connection unit, one end of which is butted on the outer side opposite to the fixing part; and

A three-dimensional displacement adjustment structure, including a first displacement adjustment unit, a second displacement adjustment unit, a third displacement adjustment unit and a base, the first displacement adjustment unit is slid on the base along a first axis direction On one side, the second displacement adjustment unit is slidably arranged above the first displacement adjustment unit along a second axis direction, and the third displacement adjustment unit is movably arranged on the second displacement adjustment unit along a third axis direction above, and one side of the third displacement adjusting unit abuts against the other end of the connecting unit.

The gripping portion is provided with a convex wall and a plurality of convex posts, the convex wall is formed on one end of the gripping adjustment unit adjacent to the first port, and the convex posts grab from two opposite outer sides of the convex wall One end of the adjustment unit protrudes outwards through the convex wall.

The grasping adjustment unit is provided with a movable part and a gradually expanding part, and the gradually expanding part is formed by gradually expanding outward from the movable part, and the second port is formed at the center of the gradually expanding part, and the movable part has A plurality of external threads are formed on the outer peripheral side of the movable part, and the first port is formed at the center of the movable part.

The first and second adjustment parts are respectively provided with a first hollow opening and a second hollow opening. The first and second hollow openings are respectively formed at the center of the first and second adjustment parts, and the first central hollow opening There are a plurality of internal threads on the periphery, and the internal threads are screwed with the external threads corresponding to the movable part. The first adjustment part is accommodated in the second hollow opening, and its upper and lower sides are respectively connected to the second adjustment part. The upper and lower sides of the fixed part are pivoted, the fixed part has a third hollow opening for accommodating the second adjusting part, and the left and right sides of the fixed part are respectively connected to the left and right sides of the second adjusting part. Phase pivot.

The grasping part clamps the projection module, the projection module has a projection lens and a base, the projection lens is set on one side of the base, and it is sleeved in the first opening, and the protrusion Clamp on the peripheral side corresponding to the base.

The base is provided with a boss, a first pillar and a first driving handle, the boss is formed by protruding from the center of one side of the base, and a first groove is recessed in the center of the base groove, and the first pillar is fixed on one side of the base, the first driving handle is pierced and combined with the first pillar, and it has an axis set on the first driving handle The first push shaft at the position and a first rotating drum, the first rotating drum is arranged on one end of the first driving handle away from the first pillar, and it is used to rotate the first pushing shaft to move back.

The first displacement adjustment unit is provided with a first groove, a first push piece of the first pillar, a second pillar, a second driving handle and a protrusion, and the first groove is formed on the first pillar. The bottom side of a displacement adjustment unit is embedded with the boss, and a first slide rail assembly is provided between the outer side of the boss and the inner side corresponding to the first groove, and the protrusion is formed on the On the top side of the first displacement adjustment unit, a second groove is recessed in its center, and the first pusher is arranged on one side of the first displacement adjustment unit to be compatible with the first pusher One end of the shaft is against each other, and the second pillar is fixed on the other side of the first displacement adjustment unit, the second driving handle is penetrated and combined on the second pillar, and it has a The second push shaft at the axis position of the second driving handle and a second rotating cylinder, the second rotating cylinder is located on one end of the second driving rotating handle away from the second pillar, and it is used to rotate the second Push the shaft to move backwards.

The second displacement adjustment unit is provided with a second groove corresponding to the aforementioned second groove and a second push piece, the second groove is formed on the bottom side of the second displacement adjustment unit, and is opposite to the protrusion Embedded, and a second slide rail assembly is provided between the outer side of the convex body and the inner side of the corresponding second groove, the second pusher is arranged on one side of the second displacement adjustment unit, and is connected with the second displacement adjustment unit One end of the second push shaft of the second driving handle abuts against each other.

The third displacement adjustment unit is arranged on the top side of the second displacement adjustment unit, and it is provided with a support part and a movable platform, and the support part is arranged between the movable platform and the second displacement adjustment unit, and it has A third driving handle, a third pusher and a third pillar, the third pusher and the third pillar are arranged on one side of the supporting part at intervals, and the third drive handle has a The third push shaft and a third rotating cylinder located at the axis position of the second driving handle, the third rotating cylinder is arranged on one end of the third driving rotating handle away from the third pillar, and it is used to rotate The third pushing shaft moves back, and the third pushing member abuts against one end of the third pushing shaft, and the movable platform moves up and down as the third pushing member is pushed.

With the design of the multi-dimensional adjustment device of the present invention, it is convenient to operate and adjust the grasped projection module, and effectively avoid the problem of shading, and more effectively achieve the effects of high adjustment accuracy and easy mass production.

【Description of drawings】

Figure 1 is an exploded perspective view of the first embodiment of the utility model;

Fig. 2 is the combined three-dimensional schematic diagram of the first embodiment of the present utility model;

Fig. 3A is another combined stereoscopic view of the first embodiment of the present utility model;

Fig. 3B is a three-dimensional schematic diagram of the implementation of the first embodiment of the present invention;

FIG. 4A is an exploded perspective view of the three-dimensional grasping adjustment structure and the projection module of the first embodiment of the present invention;

Fig. 4B is a perspective schematic diagram of the combination of the three-dimensional grasping adjustment structure and the projection module of the first embodiment of the present invention;

Fig. 5 is an exploded perspective view of the second embodiment of the present utility model;

Fig. 6 is a combined perspective view of the second embodiment of the present utility model;

Fig. 7 is an exploded perspective view of the three-dimensional displacement adjustment structure of the second embodiment of the present invention;

Fig. 8A is a combined stereoscopic diagram of the three-dimensional displacement adjustment structure of the second embodiment of the present invention;

Fig. 8B is a schematic diagram of the implementation of the three-dimensional displacement adjustment structure of the second embodiment of the present invention;

Fig. 8C is a schematic diagram of another implementation of the three-dimensional displacement adjustment structure of the second embodiment of the present invention;

Fig. 8D is a schematic diagram of another implementation of the three-dimensional displacement adjustment structure of the second embodiment of the present invention;

9 is a schematic diagram of the implementation of the multi-dimensional adjustment device and the projection module on the tablet computer in the second embodiment of the present invention;

Fig. 10 is a schematic diagram of another implementation of the multi-dimensional adjustment device and the projection module on the tablet computer according to the second embodiment of the present invention;

Fig. 11A is a schematic diagram of another implementation of the multi-dimensional adjustment device and the projection module on the tablet computer in the second embodiment of the present invention;

11B is a schematic diagram of another implementation of the multi-dimensional adjustment device and the projection module on the tablet computer in the second embodiment of the present invention;

Figure 11C is a schematic diagram of another implementation of the multi-dimensional adjustment device and the projection module on the tablet computer in the second embodiment of the present invention;

FIG. 12 is a schematic diagram of the implementation of the projection module on the tablet computer according to the second embodiment of the present invention.

The component names corresponding to the reference signs in the figure are:

Three-dimensional grasping adjustment structure... 1

Gripping adjustment unit...11

Active part... 111

External thread...1111

Expanding part...112

Grabbing Department...113

Convex wall...1131

Boss...1132

First port...114

Second port...115

Adjustment unit...116

The first adjustment department...1161

First hollow opening...11611

Internal thread...11613

The second adjustment department...1162

Second hollow opening...11621

Fixed part...1164

Third Hollow Opening...11641

First direction...X1

Second direction...Y1

Third direction...Z1

Projection module...2

Projection lens...21

Base…22

Multi-dimensional adjustment device...3

Connection unit…30

Three-dimensional displacement adjustment structure...31

Base...311

Boss...3111

First Groove...31112

First elastic...31113

First Pillar...3112

1st Drive Rotary...3113

First push shaft...31131

Drum 1...31132

The first displacement adjustment unit...312

First Groove...3121

First push piece...3122

Second Pillar...3124

2nd drive handle...3125

Second push shaft...31251

Second drum...31252

Convex...3126

Second Groove...31262

Second elastic...31263

First rail assembly...3127

First Rail...31271

Second rail...31272

Second displacement adjustment unit...313

Second Groove...3131

Second push piece...3132

Second slide rail assembly...3133

First Rail...31331

Second rail...31332

The third displacement adjustment unit...314

Support part...3141

Third drive handle...3142

Third push shaft...31421

Third Drum...31422

Third push piece...31423

Third Pillar...31424

Activity platform...3144

First axis direction...X2

Second axis direction...Y2

Third axis direction...Z2

Left projection module...41

Right projection module...42

Projection lens…411, 421

Base…412, 422

Electronics…5

Front shell…50

Shell…51

Keyboard sample...6

【detailed description】

The above-mentioned purpose of the utility model and its structural and functional characteristics will be described according to the embodiments of the accompanying drawings.

The utility model provides a three-dimensional grasping adjustment structure and a multi-dimensional adjustment device, please refer to Fig. 1 and Fig. 2, which are the perspective diagrams of the decomposition and assembly of the first embodiment of the present utility model; the three-dimensional grasping adjustment structure 1 is used for adjustment On a projection module 2, the projection module 2 in this embodiment is a micro-projection module for illustration, but it is not limited thereto. The aforementioned three-dimensional grasping and adjusting structure 1 includes a grasping and adjusting unit 11 and an adjusting unit 116. The grasping and adjusting unit 11 has a grasping part 113, a first port 114, a second port 115, and a movable part. 111 and a gradually expanding part 112, the first and second ports 114, 115 are respectively opened on one end of the grasping adjustment unit 11 and the opposite end of the grasping adjustment unit 11, and the first port 114 communicate with the second port 115 .

The aforementioned expanding portion 112 is formed by gradually expanding outward from the movable portion 111. In other words, one end of the movable portion 111 is far away from the corresponding expanding portion 112, and the other end is integrally connected to the end of the gradually expanding portion 112, so as to The grasping adjustment unit 11 is constituted; and the grasping adjustment unit 11 in this embodiment is generally funnel-shaped for illustration, but not limited thereto. And the first port 114 is formed at the center of one end of the movable part 111 (i.e., one end of the grip adjustment unit 11), and the second port 115 is formed at the other end of the second gradually expanding part 112 (i.e. Grab the center of the other end of the adjustment unit 11, and make a bell mouth in the second port 115 of this embodiment for illustration. And the aforementioned movable portion 111 has a plurality of external threads 1111 formed on the outer peripheral side of the movable portion 111 .

The above-mentioned grasping part 113 is located on one end of the grasping adjustment unit 11 adjacent to the first port 114 (ie, one end of the movable part 111), and it is provided with a convex wall 1131 and a plurality of convex pillars 1132, the convex wall 1131 The protrusion is formed on one end of the grasping adjustment unit 11 adjacent to the first port 114 (that is, one end of the movable part 111), and the protrusions 1132 are described as four protrusions 1132 in this embodiment, but not It is not limited thereto, wherein two protruding columns 1132 protrude outward from one end of the grasping adjustment unit 11 on two opposite outer sides of the protruding wall 1131 and protrude through the protruding wall 1131, and the other two protruding columns 1132 are formed from the protruding wall 1131. One ends of the other two opposite outer grasping adjustment units 11 protrude outward through the convex wall 1131 .

Referring to Fig. 4A and Fig. 4B, and referring to Fig. 1 and Fig. 3B as supplementary, the gripping part 113 is sandwiched relative to the aforementioned projection module 2, and the projection module 2 is explained by projecting a virtual keyboard in this comparative embodiment. , but not limited to this, during actual implementation, the user can design and adjust the images projected to project different virtual items according to the use requirements in advance, such as projecting a virtual drawing board, which will be presented first.

And the projection module 2 has a projection lens 21 and a base 22, the projection lens 21 is arranged on one side of the base 22, and it is sheathed in the first opening 114, so that the inside of the convex wall 1131 It will be attached on the outer peripheral side of the base 22 corresponding to this part, and the boss 1132 will clamp (or grab) the outer peripheral side of the corresponding base 22, so when the grabbing part 113 grabs the projection module 2 , the virtual keyboard image (i.e. light) projected by the projection module 2 is projected from the inside of the first port 114 toward the outside of the second port 115. Therefore, through the structural design of the present utility model, it is possible to effectively avoid It is known that adjusting manually (or using tweezers) will cover the projected light from the projection module 2. In short, the structural design of the present invention can achieve the effect of avoiding light shading.

The adjustment unit 116 has a first adjustment part 1161, a second adjustment part 1162 and a fixing part 1164. The first and second adjustment parts 1161, 1162 are respectively provided with a first hollow opening 11611 and a second hollow opening 11621, The first and second hollow openings 11611 and 11621 are respectively formed at the center of the first and second adjustment parts 1161 and 1162, and the first adjustment part 1161 is accommodated in the second adjustment part 1162 in a first direction X1 is movable, that is, the aforementioned first adjustment part 1161 is accommodated in the second hollow opening 11621 of the second adjustment part 1162, and its upper and lower sides are respectively pivoted with the corresponding upper and lower sides of the second adjustment part 1162 Suppose, in this embodiment, the first adjustment part 1161 and the second adjustment part 1162 are pivoted through multiple axes, that is, one axis passes through the upper side of the first adjustment part 1161 Together with the upper side relative to the second adjustment part 1162, the other axis passes through the lower side of the first adjustment part 1161 and is pivotally connected with the lower side relative to the second whole part, so that the first adjustment The part 1161 can rotate left and right in the second hollow opening 11621 of the second adjusting part 1162 (ie, move in the first direction X1). The first direction X1 in this embodiment is described as the X-axis direction.

The aforementioned fixing portion 1164 defines a third hollow opening 11641, the third hollow opening 11641 is formed at the center of the fixing portion 1164, and the aforementioned second adjusting portion 1162 is accommodated in the fixing portion 1164 and arranged in a second direction Y1 movable, that is, the aforementioned second adjustment part 1162 is accommodated in the third hollow opening 11641 of the fixed part 1164, and its left and right sides are respectively pivoted with the left and right sides of the corresponding fixed part 1164. For example, the second adjusting part 1162 and the fixing part 1164 are pivoted through multiple axes, that is, one axis passes through the upper side of the second adjusting part 1162 and the left side of the fixing part 1164. The sides are pivotally connected together, and the other axis passes through the right side of the second adjusting part 1162 and is pivotally connected with the right side opposite to the fixing part 1164, so that the second adjusting part 1162 can be positioned on the second side of the fixing part 1164. The three hollow openings 11641 rotate upwards and downwards (that is, move in the second direction Y1). The second direction Y1 in this embodiment is described as the Y-axis direction, and the aforementioned first adjustment part 1161 will move along with the second adjustment part 1162 in the second direction Y1, that is, in the third hollow opening 11641 When the opening of the second adjustment part 1162 is forced to rotate upwards (or downwards), the first adjustment part 1161 in the second hollow opening 11621 will also go up together with the second adjustment part 1162 Turn (or turn down).

Referring to Fig. 1, Fig. 3A, Fig. 3B, and refer to Fig. 4B supplementedly, the aforementioned grasping adjustment unit 11 is accommodated in the first adjusting unit and moves in a third direction Z1, that is, the grasping adjustment unit 11 The movable part 111 of the first adjustment unit is accommodated in the first hollow opening 11611, and the plurality of external threads 1111 on the movable part 111 are screwed with the plurality of internal threads 11613 on the inner periphery of the first hollow opening 11611, The movable part 111 of the grasping adjustment unit 11 can be rotated (or rotated) forward and backward in the first hollow opening 11611 of the first adjustment unit (that is, movable in the third direction Z1), and in this embodiment The third direction Z1 is described as the Z-axis direction. Wherein the aforementioned grip adjustment unit 11 will follow the movement of the first and second adjustment parts 1161, 1162 in the first and second directions, that is, the first adjustment part 1161 in the second hollow opening 11621 is forced to turn to the left When moving (or turning to the right), the grasping adjustment unit 11 in the first hollow opening 11611 will also be rotated to the left (or turning to the right) by the first adjustment part 1161 at the same time, and then the When the opening of the second adjusting part 1162 in the third hollow opening 11641 is forced to rotate upwards (or downwards), the first adjusting part 1161 in the second hollow opening 11621 and the upper part grab the adjustment unit 11 It will also be rotated upwards (or downwards) by the second adjustment part 1162 at the same time.

Therefore, when the assembler wants to adjust (or fine-tune) the virtual keyboard image projected by the projection module 2 to a certain inclination angle (such as about 30 degrees), the assembler needs to screw in the movable part 111 of the grasping adjustment unit 11 ( or unscrew) rotation, so that the movable part 111 rotates forward (or backward) in the first hollow opening 11611, and the projection module 2 grasped (or clamped) by the grasping part 113 is simultaneously With the rotation (or rotation) of the movable part 111, the angle direction of the virtual keyboard image projected by the projection module 2 is adjusted.

If the assembler wants to adjust (or fine-tune) the projected virtual keyboard image to the left (or right), then the first adjustment part 1161 in the second hollow opening 11621 needs to be adjusted to the left ( or to the right) to make the first adjustment part 1161 rotate leftward (or rightward) in the second hollow opening 11621 after receiving force, and at the same time, the first adjustment part 1161 and the grasping adjustment unit 11 And the projection module 2 captured on it will also rotate to the left (or to the right), and then adjust the virtual keyboard image projected by the projection module 2 to move to the left (or to the right).

If the assembler wants to adjust the projected virtual keyboard image in the forward direction (or backward direction), then it is necessary to adjust the downward direction (or upward direction) of the second adjustment part 1162 in the third hollow opening 11641 Push to make the second adjusting part 1162 turn down (or turn up) in the third hollow opening 11641 after receiving the force, and at the same time, the first adjusting part 1161 and the grasping adjustment unit 11 and the projection grasped on it The module 2 will also rotate downwards (or upwards), and then adjust the projection module 2 to project the virtual keyboard image to move forward (or backward). Wherein the above moving in the forward direction means that the projection module 2 moves the projected virtual keyboard image towards its own direction, and the above moving in the backward direction means that the projection module 2 moves the projected virtual keyboard image away from itself.

Therefore, the three-dimensional grasping adjustment structure 1 constituted by the grasping adjustment unit 11 and the adjustment unit 116 of the present invention is applied to adjust the design of the projection module 2, so that it can effectively achieve convenient grasping of the projection module 2 The virtual keyboard image is projected for adjustment (or fine-tuning), thereby effectively avoiding the effect of covering the projection light of the projection module 2 (that is, projecting the virtual keyboard image) during the adjustment process, and achieving high adjustment accuracy and easy measurement produced effect.

Please refer to Fig. 5, Fig. 6 and Fig. 7, which are the exploded and combined three-dimensional diagrams of the second embodiment of the present utility model, supplemented by referring to Fig. 11B and Fig. 12; the aforementioned multi-dimensional adjustment device 3 is applied to adjust an electronic device 5 At least one projection module installed on it, the electronic device 5 is described as a tablet computer in this embodiment, but it is not limited to this. In actual implementation, it can also be selected as a smart phone, a notebook computer, a function of the screen or other 3C electronic products. And the projection module is a micro-projection module in this embodiment, and two projection modules are installed on the electronic device 5 for illustration, that is, when this preferred example is implemented, it is through the present invention After the multi-dimensional adjustment device 3 places one of the grasped projection modules on the shell 51 (and the back shell) corresponding to the electronic device 5, the captured projection module can be adjusted by the multi-dimensional adjustment device 3 (or fine-tuning), after adjusting one projection module (such as the left projection module 41), then adjust (or fine-tune) another projection module (such as the right projection module 42), until the left and right The projection modules 41 and 42 respectively project the left half and the right half of the virtual keyboard image, which correspond to the left half and the right half of a keyboard template 6 placed in front of the housing 51 to form a complete virtual keyboard. After imaging (as shown in FIG. 11C ), the front shell 50 of the electronic device 5 and its back shell (ie, the shell 51) can be assembled and combined to form an electronic device 5 (ie, a tablet computer; as shown in FIG. 12 ) with a projected virtual keyboard. ). Wherein the left and right projection modules 41, 42 of this embodiment respectively project the left half and the right half of the virtual keyboard for illustration, and the left and right projection modules 41, 42 each have a projection lens 411, 421 and A base 412 , 422 , each of the projection lenses 411 , 421 of the left and right projection modules 41 , 42 is disposed on one side of each base 412 , 422 .

In addition, in actual implementation, the keyboard model 6 can also be omitted as shown in Figure 9 and Figure 10, and the left and right projection modules 41, 42 can be adjusted to the left and right sides of the virtual keyboard image respectively through the multi-dimensional adjustment device 3. After the half part and the right half are combined to form a complete virtual keyboard image, the front case 50 of the electronic device 5 and its back case (i.e. the case 51) can be assembled and combined to form an electronic device 5 (i.e. a flat panel) with a projected virtual keyboard. computer; as shown in FIG. 12 ), therefore, the image of the virtual keyboard projected by the left and right projection modules 41, 42 on the above-mentioned electronic device 5 can achieve the effect of high precision and convenient adjustment.

The aforementioned multi-dimensional adjustment device 3 includes a three-dimensional grasping adjustment structure 1, a connecting unit 30 and a three-dimensional displacement adjustment structure 31. The structure, connection relationship and function of the three-dimensional grasping adjustment structure 1 in this embodiment are roughly the same as those in the first embodiment described above. The three-dimensional grasping and adjusting structure 1 of the example is the same, so it will not be repeated here. The difference is that the three-dimensional grasping and adjusting structure 1 of this preferred implementation is docked on the outer side of the fixed part 1164 of the first adjusting part 1161. One end of the connection unit 30, and the other end of the connection unit 30 is connected to the corresponding three-dimensional displacement adjustment structure 31; and the aforementioned three-dimensional displacement adjustment structure 31 includes a first displacement adjustment unit 312, a second displacement adjustment unit 313, A third displacement adjustment unit 314 and a base 311, the base 311 is provided with a boss 3111, a first pillar 3112 and a first driving handle 3113, the boss 3111 is from the side opposite to the base 311 The center part is protruding upwards, and its central part is concavely provided with a first groove 31112. The first groove 31112 is formed by recessing from one end of the boss 3111 toward the opposite end of the boss 3111. And its content is provided with a first elastic member 31113 (such as a spring) that can be compressed and reset. Between one groove 3121, and one end of the first elastic member 31113 is clamped (or hooked) on the first groove 31112 adjacent to one end of the boss 3111, and the other end is clamped (or hooked) On the first groove 3121 adjusted relative to the first displacement. The three-dimensional grip adjustment structure 1 is combined with the three-dimensional displacement adjustment structure 31 through the connecting unit 30 to form a six-dimensional adjustment device (ie, the multi-dimensional adjustment device 3 ).

And the above-mentioned first pillar 3112 is fixed on one side of the base 311, the first driving handle 3113 is penetrated and combined on the first pillar 3112, and it has a set on the first driving handle 3113 The first push shaft 31131 and a first rotating cylinder 31132 at the axial center position, the first rotating cylinder 31132 is located on one end of the first driving handle 3113 away from the first pillar 3112, and it is used to rotate the first rotating cylinder 31132. The push shaft 31131 moves back and forth. The aforementioned first displacement adjustment unit 312 is slidably disposed on one side of the base 311 along a first axial direction X2, and is provided with the aforementioned first groove 3121 and a first pushing member opposite to the first pillar 3112 3122, a second pillar 3124, a second driving handle 3125 and a protrusion 3126, the first groove 3121 is formed on the bottom side of the first displacement adjustment unit 312, and is embedded with the corresponding boss 3111 . The first axis direction X2 in this embodiment is described as the X-axis direction.

A first slide rail assembly 3127 is provided between the outer side of the boss 3111 and the inner side corresponding to the first groove 3121, and the first slide rail assembly 3127 is provided with two first slide rails 31271 and two second slide rails. 31272, one side of the two first slide rails 31271 are respectively fixed on the outer sides of the corresponding boss 3111, and one side of the two second slide rails 31272 are respectively fixed on the two opposite sides of the corresponding first groove 3121. on the inner side, and they respectively abut against the two first slide rails 31271 corresponding to the boss 3111, so that the aforementioned first displacement adjustment unit 312 can move along the first slide rail assembly 3127 on the base 311. The axial direction X2 moves back, and at the same time, the three-dimensional grasping and adjusting structure 1 is driven by the connecting unit 30 that moves with the first displacement adjusting unit 312 , and moves in conjunction with the aforementioned first displacement adjusting unit 312 . The above-mentioned convex body 3126 is protrudingly formed on the top side of the first displacement adjustment unit 312, and a second groove 31262 is recessed in the center thereof, and the second groove 31262 is formed from one end of the convex body 3126 toward the opposite side. The other end of one end of the convex body 3126 is formed by recessing, and its content is provided with a second elastic member 31263 (such as a spring) that can be compressed and reset, and the second elastic member 31263 is accommodated in the second groove 31262 Between a second groove 3131 corresponding to the second displacement adjustment unit 313 , and one end of the second elastic member 31263 is clamped (or hooked) in the second groove adjacent to one end of the protruding body 3126 31262, the other end of which is clamped (or hooked) on the second groove 3131 that is adjusted relative to the second displacement.

Referring to Fig. 7, Fig. 8A, Fig. 8B, the aforementioned first pushing member 3122 is arranged on one side of the first displacement adjustment unit 312, so as to abut against one end of the first pushing shaft 31131 on the base 311. , so that the first pushing member 3122 is pushed forward by the first pushing shaft 31131 to drive the first displacement adjustment unit 312 to move away from a first original initial position along the first axis direction X2 (as shown in FIG. 8B ). At the same time, the first elastic member 31113 will be stretched along with the displacement of the first displacement adjustment unit 312; if the first push shaft 31131 retracts backward at this time, the first displacement adjustment unit 312 will move along the direction of the first axis X2 (as shown in FIG. 8B ) is pulled to the first original initial position by the elastic pulling force of the first elastic member 31113 to the retracted position of the first push shaft 31131 , and abuts against the first push shaft 31131 . And the second pillar 3124 is fixed on the other side of the first displacement adjustment unit 312, that is, the first pushing member 3122 and the second pillar 3124 are respectively arranged on different sides of the first displacement adjustment unit 312. on the side. The aforementioned first original initial position is a position where the first displacement adjusting unit 312 does not make any sliding displacement along the first axis direction X2 as shown in FIG. 8A .

The above-mentioned second driving handle 3125 is threaded and combined on the second pillar 3124, and it has a second push shaft 31251 and a second rotating cylinder 31252 arranged at the axial center of the second driving handle 3125. The second rotary drum 31252 is disposed on one end of the second driving handle 3125 away from the second support 3124 , and is used to rotate the second push shaft 31251 to move backward. And the second displacement adjustment unit 313 is slidably arranged above the first displacement adjustment unit 312 along a second axis direction Y2 (as shown in FIG. 8C ), and it is provided with the aforementioned second corresponding to the second groove 31262 The groove 3131 and a second pushing member 3132 are formed on the bottom side of the second displacement adjustment unit 313 and embedded with the protrusion 3126 . The second axis direction Y2 in this embodiment is described as the Y axis direction.

And a second slide rail assembly 3133 is provided between the outer side of the convex body 3126 and the inner side of the corresponding second groove 3131, and the second slide rail assembly 3133 is provided with two first slide rails 31331 and two second slide rails 31272, One side of the first slide rail 31331 of the second slide rail assembly 3133 is respectively fixed on the outer sides of the corresponding convex body 3126, and one side of the second slide rail 31272 of the second slide rail assembly 3133 is fixed respectively. It is arranged on the two opposite inner sides corresponding to the second groove 3131, and they are respectively attached to the two first slide rails 31331 corresponding to the convex body 3126, so that the aforementioned second displacement adjustment unit 313 can pass through the second slide rails. The component 3133 can move back and forth along the second axis direction Y2 on the first displacement adjustment unit 312, and at the same time, the three-dimensional grasping adjustment structure 1 will be driven by the connecting unit 30 that is displaced with the second displacement adjustment unit 313, and is connected with The aforementioned second displacement adjustment unit 313 is displaced in unison.

The second pushing member 3132 is arranged on one side of the second displacement adjustment unit 313, and is opposed to one end of the second push shaft 31251 of the second driving handle 3125 on the first displacement adjustment unit 312. push the second pushing member 3132 forward by the second pushing shaft 31251 to drive the second displacement adjusting unit 313 away from a second original initial position along the second axis direction Y2 (as shown in FIG. 8C ). At the same time, the second elastic member 31263 will be stretched along with the displacement of the second displacement adjustment unit 313. If the second push shaft 31251 is retracted at this time, the second displacement adjustment unit 313 will move along the second axis. The direction Y2 is pulled toward the second original initial position (as shown in FIG. 8A ) by the elastic pulling force of the second elastic member 31263 to the retracted position of the second push shaft 31251 , and abuts against the second push shaft 31251 . The aforementioned second original initial position is a position where the second displacement adjustment unit 313 does not make any sliding displacement along the second axis direction Y2 as shown in FIG. 8A .

Referring to Fig. 7 and Fig. 8D, and referring to Fig. 6, the aforementioned third displacement adjustment unit 314 is movably arranged above the second displacement adjustment unit 313 along a third axis direction Z2, that is, the third displacement adjustment unit 314 It is arranged on the top side of the second displacement adjustment unit 313, and can be displaced upward or downward (as shown in FIG. 8D ), and one side of the third displacement adjustment unit 314 is connected to the other end of the connecting unit 30, And when the third displacement adjustment unit 314 is displaced along the third axis direction Z2, the aforementioned three-dimensional grasping adjustment structure 1 will be driven by the connecting unit 30 that is displaced with the third displacement adjustment unit 314, and the aforementioned third displacement The adjustment unit 314 moves in unison. The third axis direction Z2 in this embodiment is the Z axis direction for illustration.

The aforementioned third displacement adjustment unit 314 is provided with a support portion 3141 and a movable platform 3144, the support portion 3141 is located between the movable platform 3144 and the second displacement adjustment unit 313, and it has a third driving handle 3142, a The third pushing piece 31423 and a third pillar 31424, the third pushing piece 31423 and the third pillar 31424 are spaced apart on one side of the support portion 3141, and the third driving handle 3142 has a The third push shaft 31421 and a third rotating drum 31422 at the axial center position of the second driving handle 3125, the third rotating drum 31422 is located on one end of the third driving rotating handle 3142 away from the third pillar 31424, It is used to rotate the third push shaft 31421 to move back, and the third push piece 31423 is pushed against one end of the third push shaft 31421, so that the third push piece 31423 is pushed forward by the third push shaft 31421 push out, and push the movable platform 3144 along the third axis direction Z2 (that is, upward; as shown in Figure 8D) away from a third original initial position displacement, if the third push shaft 31421 retracts backward at this time, the The third pushing member 31423 will retract back along with the third pushing shaft 31421, and at the same time, the movable platform 3144 will move to the third original initial position (as shown in FIG. 8A ) along the third axis direction Z2 (ie downward). To the position where the third pushing shaft 31421 is retracted, in other words, the movable platform 3144 will move up and down as the third pushing member 31423 is pushed. The above-mentioned third original initial position is a position where the third displacement adjustment unit 314 does not make any active displacement along the third axis direction Z2 as shown in FIG. 8A .

Here is an example to illustrate:

Please refer to Fig. 9, Fig. 11A, Fig. 11B, when the assembler wants to adjust (or fine-tune) the right half of the virtual keyboard image projected by the right projection module 42 of the upper casing 51 of the tablet computer (or fine-tune) The second adjustment part 1162 in the third hollow opening can be pushed upwards first, so that the second adjustment part 1162 can rotate (or move) upwards in the third hollow opening after receiving force, and at the same time, the first adjustment Part 1161 and the grasping adjustment unit 11 and the projection module grasped on it will also rotate upwards, so that the right half of the virtual keyboard image projected by the right projection module 42 will move backward until the right projection module 42 After group 42 projects the upper and lower edges of the right half of the virtual keyboard image corresponding to the upper and lower edges of the right half of the keyboard template 6 (as shown in Figure 11B), the first section of the aforementioned first zone is turned. The rotary drum 31132 rotates, and then drives the first push shaft 31131 to extend forward and pushes the relative first push member 3122, so that the first push member 3122 is pushed by the first push shaft 31131 to drive the first displacement The adjustment unit 312 is displaced away from the first original initial position along the first axis direction X2 (that is, drives the first displacement adjustment unit 312 to move toward the left half of the virtual keyboard image), at this time, the three-dimensional capture adjustment structure 1 will follow The first displacement adjustment unit 312 moves together and moves until the left and right edges of the right half of the virtual keyboard projected by the left and right projection modules 41 and 42 correspond to the left and right edges of the right half of the keyboard template 6 ( As shown in FIG. 11C ), the adjustment can be completed.

In addition, if the assembler is fine-tuning the projection module, the key fonts and patterns on the right half (or left half) of the virtual keyboard projected by the projection module do not correspond to the right half of the keyboard template 6 (or the left half), the assembler can fine-tune the inclination angle of the projected virtual keyboard image by grabbing the adjustment unit 11, or use the first adjustment part 1161 to fine-tune the projection The virtual keyboard image moves to the left (or right).

Therefore, through the connecting unit 30 of the present invention, the three-dimensional grasping adjustment structure 1 and the three-dimensional displacement adjustment structure 31 are respectively connected to form the aforementioned multi-dimensional adjustment device 3, and are applied to adjust (or fine-tune) each projection module on the electronic device 5. The design makes it possible to effectively adjust (or fine-tune) the virtual keyboard image projected by the captured projection module, and effectively avoid blocking the projection light of the projection module during the adjustment process (that is, to project the virtual keyboard image) ), and can achieve the effect of high adjustment accuracy and easy mass production.

In addition, since the connection unit 30 of the present invention is located in the small space between the electronic device 5 and the head shadow virtual keyboard image, the three-dimensional grasping and adjusting structure 1 connected to one end of the connection unit 30 can facilitate the adjustment of the projection model to be adjusted. The group is fine-tuned, so that the light projected by the projection module can be effectively avoided, and the effect of convenient adjustment can be achieved.

The utility model described above has the following advantages compared to known

1. It has the effects of high adjustment accuracy and easy mass production.

2. It has the effect of avoiding shading.

3. It has the problem of avoiding narrow adjustment space.

4. It has the effect of convenient operation and adjustment.

The above is only a preferred embodiment of the utility model, and all changes made by utilizing the above-mentioned method, shape, structure, and device of the utility model should be included in the scope of rights of the present application.

Claims (14)

1. a three-dimensional crawl adjust structure, be applied on a projection module corresponding to adjustment, it is characterized in that, described three-dimensional crawl adjust structure comprises:

One captures adjustment unit, there is a crawl section, one first port and one second port, on one end that this first and second port is opened in this crawl adjustment unit respectively and its other end, this first port is communicated with this second port, and this crawl section is located on one end of this crawl adjustment unit of this first port adjacent;

One adjustment unit, there is one first adjustment part, one second adjustment part and a fixed part, this first adjustment part to be located in this second adjustment part and movable at a first direction, this second adjustment part to be located in this fixed part and in a second direction activity, and this crawl adjustment unit to be then located in this first adjustment unit and movable at a third direction; And

Wherein this first adjustment part can along with this second adjustment part be in this second direction activity, and this crawl adjustment unit can be movable in this first and second direction along with this first and second adjustment part.

2. three-dimensional according to claim 1 captures adjust structure, it is characterized in that: described crawl section is provided with a convex wall and plural projection, this convex wall is formed on one end of this crawl adjustment unit of this first port adjacent, and this projection extends through this convex wall from convex one end of this crawl adjustment unit of two opposite exterior lateral sides of this convex wall and formed.

3. three-dimensional according to claim 2 captures adjust structure, it is characterized in that: described crawl adjustment unit is provided with a movable part and a flaring part, this flaring part formed from the outside flaring of this movable part, and this second port is formed in the center of this flaring part, this movable part has plural external thread, this external thread is formed on the outer circumferential side of this movable part, and this first port is formed in the center of this movable part.

4. three-dimensional according to claim 3 captures adjust structure, it is characterized in that: described first, two adjustment parts offer one first hollow open and one second hollow open respectively, this is first years old, two hollow open be respectively formed at this first, the centre of two adjustment parts, and this first hollow open inner peripheral has plural internal thread, this internal thread is established with this external thread phase spiral shell of this movable part relative, this first adjustment part is installed with in this second hollow open, and on it, downside respectively with to should the second adjustment part upper, downside is pivoted mutually, this fixed part offers the 3rd hollow open that is installed with this second adjustment part, and a left side for this fixed part, right side respectively with to should the left side of the second adjustment part, right side is pivoted mutually.

5. three-dimensional according to claim 2 captures adjust structure, it is characterized in that: this projection module of described crawl section sandwiched, this projection module has a projection lens and a base, this projection lens is located on the side of this base, and it is sheathed in this first port, and this projection is clamped should on all sides of base.

6. a multidimensional adjusting gear, be applied at least one projection module that adjustment one electronic installation is installed, it is characterized in that, described multidimensional adjusting gear comprises:

One three-dimensional crawl adjust structure, comprises:

One captures adjustment unit, there is a crawl section, one first port and one second port, on one end that this first and second port is opened in this crawl adjustment unit respectively and its other end, this first port is communicated with this second port, and this crawl section is located on one end of this crawl adjustment unit of this first port adjacent;

One adjustment unit, there is one first adjustment part, one second adjustment part and a fixed part, this first adjustment part to be located in this second adjustment part and movable at a first direction, this second adjustment part to be located in this fixed part and in a second direction activity, and this crawl adjustment unit is then located in relatively movable at a third direction in this first adjustment unit; And

It is characterized in that: described first adjustment part can along with this second adjustment part be in this second direction activity, and this crawl adjustment unit can be movable in this first and second direction along with this first and second adjustment part;

One linkage unit, on the outside of its one end docking this fixed part relative; And

One three-D displacement adjust structure, comprise one first adjustment of displacement unit, one second adjustment of displacement unit, a triple motion adjustment unit and a pedestal, this the first adjustment of displacement unit is slidedly arranged on the side of this pedestal along one first direction of principal axis, this the second adjustment of displacement unit is slidedly arranged on the top of this first adjustment of displacement unit along one second direction of principal axis, this triple motion adjustment unit is located at the top of this second adjustment of displacement unit along one the 3rd direction of principal axis activity, and the other end of this linkage unit is docked in the side of this triple motion adjustment unit.

7. multidimensional adjusting gear according to claim 6, it is characterized in that: described crawl section is provided with a convex wall and plural projection, this convex wall is formed on one end of this crawl adjustment unit of this first port adjacent, this projection from convex one end of this crawl adjustment unit of two opposite exterior lateral sides of this convex wall extend through this convex wall form.

8. multidimensional adjusting gear according to claim 7, it is characterized in that: described crawl adjustment unit is provided with a movable part and a flaring part, this flaring part formed from the outside flaring of this movable part, and this second port is formed in the center of this flaring part, this movable part has plural external thread, this external thread is formed on the outer circumferential side of this movable part, and this first port is formed in the center of this movable part.

9. multidimensional adjusting gear according to claim 8, it is characterized in that: described first, two adjustment parts offer one first hollow open and one second hollow open respectively, this is first years old, two hollow open be respectively formed at this first, the centre of two adjustment parts, and this first center hollow opening inner peripheral has plural internal thread, this internal thread is established with this external thread phase spiral shell of this movable part relative, this first adjustment part is installed with in this second hollow open, and on it, downside respectively with to should the second adjustment part upper, downside is pivoted mutually, this fixed part offers the 3rd hollow open that is installed with this second adjustment part, and a left side for this fixed part, right side respectively with to should the left side of the second adjustment part, right side is pivoted mutually.

10. multidimensional adjusting gear according to claim 7, it is characterized in that: this projection module of described crawl section sandwiched, this projection module has a projection lens and a base, this projection lens is located on the side of this base, and it is sheathed in this first port, and this projection clamps should on all sides of base.

11. multidimensional adjusting gears according to claim 7, it is characterized in that: described pedestal is provided with a boss, one first pillar and one first drives turning handle, this boss protrudes out formation from the centre of the side of this pedestal, and its centre is arranged with one first groove, and this first pillar is installed on a side of this pedestal, this the first driving turning handle wears and is combined on this first pillar, and it has the first push shaft and one first rotating cylinder of the shaft core position being located at this first driving turning handle, this first rotating cylinder is located at and is driven on one end of turning handle away from first of this first pillar, it is in order to rotate this first push shaft shift reciprocately.

12. multidimensional adjusting gears according to claim 11, it is characterized in that: described first adjustment of displacement unit is provided with one first groove, first yoke frame of one this first pillar, one second pillar, one second drives turning handle and a convex body, this first groove is formed in the bottom side of this first adjustment of displacement unit, and be embedded mutually with this boss, and the outside of this boss and to being provided with one first slide track component between the inner side of the first groove, this convex body projection is formed on the top side of this first adjustment of displacement unit, and its centre is arranged with one second groove, and this first yoke frame is then arranged on a side of this first adjustment of displacement unit, to support mutually with one end of this first push shaft, and this second pillar is fixedly arranged on another side of this first adjustment of displacement unit, this the second driving turning handle wears and is combined on this second pillar, and it has the second push shaft and one second rotating cylinder of the shaft core position being located at this second driving turning handle, this second rotating cylinder is located at and is driven on one end of turning handle away from second of this second pillar, it is in order to rotate this second push shaft shift reciprocately.

13. multidimensional adjusting gears according to claim 12, it is characterized in that: described second adjustment of displacement unit is provided with the second groove and one second yoke frame of corresponding aforementioned second groove, this second groove is formed in the bottom side of this second adjustment of displacement unit, and be embedded mutually with this convex body, and the outside of this convex body and to should inside the second groove between be provided with one second slide track component, this second yoke frame is arranged on a side of this second adjustment of displacement unit, and second drives one end of the second push shaft of turning handle to offset to push up with this.

14. multidimensional adjusting gears according to claim 13, it is characterized in that: described triple motion adjustment unit is located on the top side of this second adjustment of displacement unit, and it is provided with a support portion and a movable platform, this support portion is located between this movable platform and the second adjustment of displacement unit, and it has one the 3rd driving turning handle, one the 3rd yoke frame and one the 3rd pillar, 3rd yoke frame and the 3rd pillar spacer are arranged on a side of this support portion, and the 3rd driving turning handle has the 3rd push shaft and one the 3rd rotating cylinder of the shaft core position being located at this second driving turning handle, 3rd rotating cylinder is located at and is driven on one end of turning handle away from the 3rd of the 3rd pillar, it is in order to rotate the 3rd push shaft shift reciprocately, and one end of the 3rd yoke frame and the 3rd push shaft offsets and pushes up, and this movable platform with the 3rd yoke frame by promote and on, bottom offset.