CN101207985A - Magnetic force assistant slide locating mechanism - Google Patents

Magnetic force assistant slide locating mechanism Download PDF

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Publication number
CN101207985A
CN101207985A CNA2006101686860A CN200610168686A CN101207985A CN 101207985 A CN101207985 A CN 101207985A CN A2006101686860 A CNA2006101686860 A CN A2006101686860A CN 200610168686 A CN200610168686 A CN 200610168686A CN 101207985 A CN101207985 A CN 101207985A
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China
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magnetic
magnet
platform
magnetic pole
locating mechanism
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CNA2006101686860A
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Chinese (zh)
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王京禄
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BenQ Corp
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BenQ Corp
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Priority to CNA2006101686860A priority Critical patent/CN101207985A/en
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Abstract

The invention discloses a sliding locating mechanism assisted by magnets, and the mechanism comprises a first platform and a second platform. The first platform is combined with a double-sided rack and two first magnets. The two first magnets are arranged on the two ends of the double-sided rack and provided with first magnetic poles and second magnetic poles, and the first magnetic poles of the two first magnets are arranged oppositely to each other. The second platform is combined with two magnetic gear wheels which are articulated with the two sides of the double-sided rack, and the two magnetic gear wheels are both provided with the first magnetic poles and the second magnetic poles. When a relative sliding motion is acted between the first platform and the second platform, the two magnetic gear wheels are driven to rotate by meshing with the double-sided rack in a rotating way; when the two magnetic gear wheels are rotated to the middle of the double-sided rack, the first magnetic poles of the two magnetic gear wheels repel each other; when the two magnetic gear wheels are rotated to the two ends of the double-sided rack, the second magnetic poles of the two magnetic gear wheels and the first magnetic poles of the first magnets attract each other.

Description

Magnetic force assistant slide locating mechanism
Technical field
The present invention relates to a kind of slide locating mechanism, particularly relate to a kind of by the auxiliary slide locating mechanism of magnetic force.
Background technology
Take a broad view of existing unpowered assistant slide locating mechanism, mostly possess the relative not moving part with of a relative movable piece is arranged, and utilize gravitation, surface tension and magnetic force etc. to be present in natural contact force to guide this moving apart from power relative to movable piece with super, and the guiding by the slip arrangement for guiding, be positioned to select location and this relative movable piece is able to automatically or semi-automatically slides.
Wherein, gravitation is to utilize the gravity of mass and guide this relative to the moving of movable piece mostly, owing to drive this relative to the moving of movable piece, must overcome sizable mechanical friction power usually, so usually must be in conjunction with heavier mass, so normally be used in relatively large mechanical device.
Secondly, for utilizing surface tension person, normally utilize liquid to draw this moving relative to moving part not and this relative to the surface tension difference of movable piece relative to movable piece with this, because surface tension is all very little usually, so be only applicable to the unpowered auxiliary slide locating mechanism of atomic little (as micron and nano-grade size).
At last, for utilizing the auxiliary slide locating mechanism of magnetic force, because magnetisable material possesses and two magnetic poles is arranged (being the N utmost point and the S utmost point), it possesses same pole can be mutually exclusive, the characteristic that the phase different pole can be attracted each other, and repulsion is moderate with the strength that attracts mutually, so can be used for the unpowered assistant slide locating mechanism of stock size, be particularly useful for the slip positioning function of general portable electronic devices, as sliding cover type mobile phone.
At this,, further above-described correlation technique is illustrated enumerating a kind of existing magnetic force assistant slide locating mechanism that is applied to portable electronic devices especially.See also Fig. 1, it shows the three-dimensional appearance exploded view of existing magnetic force assistant slide locating mechanism.As shown in the figure, a magnetic force assistant slide locating mechanism 100 possesses a upper plate 1, a lower plate 2 and a slip arrangement for guiding 3 is arranged.Wherein, upper plate 1 possesses one first working face 11 and three magnet 12,13 and 14 that are incorporated into first working face 11, and magnet 12,13 and 14 is along the bearing of trend of a central shaft A0 and dispose.This lower plate 2 possesses has one second working face 21 and to be incorporated into the magnet 22 of this second working face 21, and this magnet 22 disposes corresponding to the position of central shaft A0.
Slip arrangement for guiding 3 includes a pair of guide channel 31 and a pair of guide rail 32 that is incorporated into these lower plate 2 two lateral margins that is incorporated into these upper plate 1 two lateral margins.Simultaneously, upper plate 1 utilizes this that guide channel 31 is combined with the cooperation of guide rail 32 with lower plate 2, and after the two combination, lower plate 2 can carry out relative sliding motion corresponding to the glide direction I0 of central shaft A0 to upper plate 1 along one.
See also Fig. 2, the local element cutaway view of 2-2 section in its displayed map 1 (omitting this slip arrangement for guiding 3).As shown in the figure, the magnet 12 and 14 the S utmost point are incorporated into first working face 11, and its N utmost point is then towards second working face 21.The N utmost point of magnet 13 is incorporated into first working face 11, and its S utmost point is then towards second working face 21.Simultaneously, the N utmost point of magnet 22 is incorporated into second working face 21, and its S utmost point is then towards first working face 11.
Please continue to consult Fig. 2 A to Fig. 2 E, it shows that lower plate utilizes the auxiliary of magnetic force and carries out a series of actions schematic diagram that a slide relative is moved with respect to upper plate.Shown in Fig. 2 A, when magnet 22 is positioned at the correspondence position of magnet 12, the S utmost point of magnet 22 is the N utmost points towards magnet 12, magnet 22 can be subjected to magnet 12 act on magnet 22 an attraction F1 traction and make lower plate 2 be located in magnet 22 and magnet 12 corresponding positions, so must apply an external force F0 to lower plate 2 along glide direction I0, can make the traction of magnet 22 opposing attraction F1, and make lower plate 2 carry out relative sliding motion to upper plate 1 along glide direction I0.
Shown in Fig. 2 B, because the S utmost point position of the S utmost point adjacent magnet 13 of magnet 22, when magnet 22 moves to magnet 12 and 13 s' position with lower plate 2, magnet 22 can be subjected to the obstruction that magnet 13 acts on a repulsive force F2 of magnet 22, when sliding into the position of approaching corresponding to magnet 13 gradually along with magnet 22, repulsive force F2 can increase gradually, and attraction F1 then can be reduced to an attraction F1 ' gradually.But, still need continue to apply this external force F0, to overcome the reverse resistance that attraction F1 ' and repulsive force F2 cause magnet 22 along glide direction I0.
Shown in Fig. 2 C, when magnet 22 is positioned at the correspondence position of magnet 13, the S utmost point of magnet 22 is the S utmost points towards magnet 13, magnet 22 can be subjected to the repulsion that magnet 13 acts on a repulsive force F2 ' of magnet 22, so still must apply external force F0 to lower plate 2 along glide direction I0, can make the repulsion of magnet 22 opposing repulsive force F2 ', and make lower plate 2 carry out relative sliding motion to upper plate 1 along glide direction I0.
Shown in Fig. 2 D, because the N utmost point position of the S utmost point adjacent magnet 14 of this magnet 22, when magnet 22 moves to magnet 13 and 14 s' position with lower plate 2, magnet 22 can be subjected to the traction that magnet 14 acts on an attraction F3 of magnet 22, when sliding into the position of approaching corresponding to magnet 14 gradually along with magnet 22, attraction F3 can increase gradually, and repulsive force F2 ' then can be reduced to a repulsive force F2 gradually ".Because repulsive force F2 " with attraction F3 along glide direction I0 to magnet 22 make a concerted effort identically with external force F0, can make the lower plate continuation upper plate 1 be carried out relative sliding motion so needn't apply external force F0 again along glide direction I0.
Shown in Fig. 2 E, when magnet 22 is positioned at the correspondence position of magnet 14, the S utmost point of magnet 22 is the N utmost points towards magnet 14, and magnet 22 can be subjected to the attraction that magnet 14 acts on an attraction F3 ' of magnet 22, so can make lower plate 2 be located in magnet 22 and magnet 14 corresponding positions.
Such as the personage who is familiar with correlation technique all can understand: in above-described magnetic force assistant slide locating mechanism 100, because magnet 12,13,14 and 24 relative allocation position, and to each other the magnetic pole similarities and differences caused to inhale with the relation of repelling each other mutually be the key of this technology of realization.
Summary of the invention
Technical problem and purpose that institute of the present invention desire solves: it is described to take a broad view of above prior art, because the relative allocation position of magnet, and to each other the magnetic pole similarities and differences caused inhale the key that realizes this technology with repulsion series mutually, so in the practice utilization, enough inhale mutually and the strength of repelling each other in order to produce, often must adopt bigger magnet or the stronger magnet of magnetic force of dimensions, just possess to have and enough inhale mutually and the strength of repelling each other.
Because between upper plate and lower plate, at least must leave the space of two N magnetic poles of enough bearings and two S magnetic poles, once adopt the bigger magnet of dimensions, can strengthen the space of upper plate and lower plate, certainly will to strengthen the size of whole magnetic force assistant slide locating mechanism thus.
If adopt the magnet of magnetic very strong (magnetic flux that is unit space is quite big), the changes of magnetic field amount that produces in sliding process will become quite big, will can cause great electromagnetic interference to electronic installation especially.
Moreover, no matter adopt above-mentioned which kind of method, because above-mentioned technology is to utilize magnetic pole to inhale mutually with the effect that repels each other fully just to be achieved, owing to do not have any resiliency therebetween, so whole motion process builds under the framework that pulls at and scold suddenly, Once you begin break through resistance and during setting in motion, the impulsive force that is present between upper plate and lower plate will become quite big, and can produce negative influence the running stability of electronic installation.
Edge this, main purpose of the present invention is to provide a kind of magnetic force assistant slide locating mechanism, it disposes the magnet of several magnetic pole lateral dispersion configurations between two platforms, under distance between reducing between two platforms, provide enough to inhale mutually and realize the auxiliary technology of sliding and locating of magnetic force with the strength of repelling each other.
Of the present invention time a purpose is to provide a kind of magnetic force assistant slide locating mechanism, and it disposes the magnet of several magnetic pole lateral dispersion configurations between two platforms, in order to reduce the changes of magnetic field amount that relative motion caused between each magnet.
Another object of the present invention is to provide a kind of magnetic force assistant slide locating mechanism, configuration one buffering arrangement for guiding between two platforms, the impact that when realizing the technology of the auxiliary location of sliding of magnetic force this magnetic force assistant slide locating mechanism is caused in order to minimizing.
The technological means that the present invention deals with problems:
The present invention provides a kind of magnetic force assistant slide locating mechanism for solving the technological means that prior art problems adopted, and it possesses one first platform is arranged, one second platform and a slip arrangement for guiding.First platform has one first working face, on first working face, disposes a two-sided tooth bar and 2 first magnet.Wherein, 2 first above-mentioned magnet configuration are in the two ends of this two-sided tooth bar, and it possesses first magnetic pole and one second magnetic pole, and first magnetic pole of 2 first above-mentioned magnet disposes toward each other.
Second platform tool has one second working face, on second working face, disposes two magnetic gears that are engaged in these two-sided tooth bar two sides respectively, and above-mentioned two magnetic gears all possess first magnetic pole and second magnetic pole are arranged.
The slip arrangement for guiding is incorporated into two lateral margins of first platform and second platform, in order in conjunction with first platform and second platform, and makes between first platform and second platform and can carry out a relative sliding motion.Carry out relative sliding motion when between first platform and second platform, and when making above-mentioned two magnetic gears turn in the middle of this two-sided tooth bar the place, first magnetic pole of above-mentioned two magnetic gears is toward each other and mutually exclusive.Carry out relative sliding motion when between first platform and second platform, when making above-mentioned two magnetic gears turn to two ends of two-sided tooth bar, second magnetic pole of above-mentioned two magnetic gears is inhaled mutually with first magnetic pole of first magnet.
The present invention's effect against existing technologies:
Be compared to the existing magnetic force assistant slide locating mechanism that applies to portable electronic devices, because between the present invention's two platforms, the magnetic pole of several magnet is landscape configuration, so not only can effectively reduce the spacing between two platforms, to reduce the overall dimensions of this portable electronic devices, more can effectively reduce the changes of magnetic field amount that relative motion caused between each magnet, and then reduce it electromagnetic interference that this portable electronic devices caused.In addition, because the present invention is configuration one a buffering arrangement for guiding between two platforms, the impact that this magnetic force assistant slide locating mechanism is caused when reduce realizing the technology of the auxiliary location of sliding of magnetic force increases the integrated operation stability of this electronic installation.
Specific embodiment of the present invention will be by following embodiment and graphic being further described.
Description of drawings
Fig. 1 is the three-dimensional appearance exploded view of existing magnetic force assistant slide locating mechanism;
Fig. 2 is the local element cutaway view of 2-2 section among Fig. 1;
Fig. 2 A to Fig. 2 E is that lower plate utilizes the auxiliary of magnetic force and carries out a series of actions schematic diagram that a slide relative is moved with respect to upper plate;
Fig. 3 is the three-dimensional appearance exploded view of first embodiment of the invention;
Fig. 3 A to Fig. 3 C is that first platform of first embodiment of the invention utilizes the auxiliary of magnetic force and carries out a series of actions schematic diagram that a slide relative is moved with respect to second platform;
Fig. 4 is the stereo appearance figure of second embodiment of the invention, that is shows that the present invention is applied to the schematic diagram of the solid of a slide electronic device.
The main element symbol description:
100 magnetic force assistant slide locating mechanisms
1 upper plate
2 lower plates
3 slip arrangement for guiding
11 first working faces
12,13,14,22 magnet
21 second working faces
31 guide channels
32 guide rails
200 magnetic force assistant slide locating mechanisms
4 first platforms
41 first working faces
42 two-sided tooth bars
421,422 tooth-strip parts
43,44 first magnet
5 second platforms
51 second working faces
52,53 magnetic gears
521,531 second magnet
522,532 pin-joint mechanisms
6 slip arrangement for guiding
61 guide rails
62 guide channels
The 200a slide electronic device
The 4a pedestal
41a first working face
The 5a slip lid
6a slip arrangement for guiding
The 61a guide rail
The 62a guide channel
7 cover plate
The A0 central shaft
The I0 glide direction
I0 ' glide direction
I first direction of rotation
II second direction of rotation
III covers direction
F0, F0 ' external force
F1, F1 ', F3, F3 ' attraction
F2, F2 ', F2 " repulsive force
F4, F4 ", F5, F5 " attraction
F4 ', F5 ' repulsive force
Embodiment
See also Fig. 3, it shows the three-dimensional appearance exploded view of first embodiment of the invention.As shown in the figure, a magnetic force assistant slide locating mechanism 200 includes one first platform 4, one second platform 5 and a slippage arrangement for guiding 6.
First platform 4 has one first working face 41, on first working face 41, disposes a two- sided tooth bar 42 and 2 first magnet 43 and 44.Wherein, this first magnet 43 and 44 is disposed at the two ends of two-sided tooth bar 42, it all possesses one first magnetic pole is arranged (is the N utmost point in the present embodiment, below replace with the N utmost point) with one second magnetic pole (be the S utmost point in the present embodiment, below replace with the S utmost point), and first magnetic pole of first magnet 43 and 44 disposes toward each other, and the two side faces of this two-sided tooth bar 42 then has a tooth- strip part 421 and 422 respectively.
Second platform 5 possesses one second working face 51, and second working face 51 is towards first working face 41.On second working face 51, dispose two magnetic gears 52 and 53, and magnetic gear 52 and 53 is engaged in the tooth- strip part 421 and 422 of two-sided tooth bar 42 two side faces respectively.Wherein, magnetic gear 52 includes one second magnet 521 and a pin-joint mechanism 522.Wherein, second magnet 521 is embedded at magnetic gear 52, and is articulated on second working face 51 by pin-joint mechanism 522.Magnetic gear 53 includes one second magnet 531 and a pin-joint mechanism 532.Wherein, second magnet 531 is embedded at magnetic gear 53, and is articulated on second working face 51 by pin-joint mechanism 532.
Slip arrangement for guiding 6 includes pair of guide rails 61 and a pair of and this guide channel 62 that guide rail 61 is cooperated.Wherein, this is incorporated into two lateral margins of this first platform 4 respectively to guide rail 61, and this is incorporated into two lateral margins of this second platform 5 respectively to guide channel 62, with so that can carry out a relative sliding motion along a glide direction I0 ' between first platform 4 and second platform 5.
Though in the present embodiment, first magnetic pole is the N utmost point, second magnetic pole is the S utmost point, and this is incorporated into two lateral margins of first platform 4 and second platform 5 respectively to guide rail 61 and this to guide channel 62; Yet the personage who is familiar with correlation technique such as can both understand, and in the practice utilization, first magnetic pole can be the S utmost point, and at this moment, second magnetic pole is necessary for the N utmost point.In addition, this also can be incorporated into two lateral margins of this second platform 5 and this first platform 4 respectively to guide rail 61 and this to guide channel 62.
See also Fig. 3 A to Fig. 3 C, it shows that first platform utilizes the auxiliary of magnetic force and carries out a series of actions schematic diagram that a slide relative is moved with respect to second platform.As shown in Figure 3A, when magnetic gear 52 is close to 53 or contacts first magnet 43, the N utmost point of extremely contiguous first magnet 43 of the S of second magnet 521 of magnetic gear 52, the S utmost point of second magnet 531 of magnetic gear 53 is the N utmost point of contiguous first magnet 43 also, therefore magnetic gear 52 can be subjected to the effect of two attraction F4 and F5 respectively with 53 and attract mutually with first magnet 43, so can be in order to second platform 5 is positioned an ad-hoc location of first platform 4.
When the user applies an external force F0 ' (being shown in Fig. 3) to this second platform 5, when making 5 beginnings of second platform carry out relative sliding motion along glide direction I0 ' and to first platform 4, can drive the tooth-strip part 411 and 412 and that magnetic gear 52 and 53 is engaged in two-sided tooth bar 42 two side faces respectively respectively along one first direction of rotation I and one second direction of rotation II rotation, when magnetic gear 52 and 53 turns to the middle place (shown in Fig. 3 B) of two-sided tooth bar 42, second magnet 521 and 531 the N utmost point are toward each other, repel each other so can make magnetic gear 52 and 53 be subjected to the effect of two repulsive force F4 ' and F5 '.
When 5 continuation of second platform are carried out relative sliding motion along glide direction I0 ' and to first platform 4, magnetic gear 52 and 53 s' repulsive force, can order about the tooth-strip part 411 and 412 that magnetic gear 52 and 53 is engaged in two-sided tooth bar 42 two side faces respectively, and continue automatically to rotate along the first direction of rotation I and the second direction of rotation II respectively, so can automatically carry out relative sliding motion to first platform 4 in order to auxiliary second platform 5 along glide direction I0 '.
When magnetic gear 52 is close to 53 or contacts first magnet 44, the N utmost point of extremely contiguous first magnet 43 of the S of second magnet 521 of magnetic gear 52, the S utmost point of second magnet 531 of magnetic gear 53 is the N utmost point of contiguous this first magnet 43 also, therefore this magnetic gear 52 and 53 can be subjected to two attraction F4 " and F5 " effect and attract each other with this first magnet 43 respectively, so can be in order to this second platform 5 is positioned another ad-hoc location of this first platform 4.
Such as the personage who is familiar with correlation technique can both understand, be compared to existing auxiliary slip location technology between the plate up and down, first magnet 43 provided by the present invention and 44, and second magnet 521 and 531 the N utmost point and S utmost point landscape configuration between this first platform 4 and this second platform 5, so when this technology of realization, can effectively save its configuration space.In addition, by this configuration mode, can effectively solve the high electromagnetic interference problem of deriving because magnetic force too concentrates on ad-hoc location (as disposing the position of four magnet in the prior art).
Please continue to consult Fig. 4, it shows the stereo appearance figure of second embodiment of the invention, that is shows that the present invention is applied to the schematic diagram of the solid of a slide electronic device.As shown in the figure, be to replace this first platform 4, this second platform 5 and this slip arrangement for guiding 6 respectively in the present embodiment with a pedestal 4a, a slip lid 5a and another slip arrangement for guiding 6a, and will be in order to form a slide electronic device 200a.Pedestal 4a possesses one first working face 41a is arranged, this first working face 41a except the element (this figure only shows this first magnet 43) that disposes first platform 4 and possessed, more configurable several operational and controlled key buttons 45.Slip lid 5a possesses one second working face 51a is arranged, the second working face 51a except the element that disposes second platform 5 and possessed, a more configurable display floater 54.
Slip arrangement for guiding 6a includes pair of guide rails 61a and a pair of and this guide channel 62a that guide rail 61a is cooperated.Wherein, this is incorporated into two lateral margins of this pedestal 4a respectively to guide rail 61a, and this is incorporated into two lateral margins of this slip lid 5a respectively to guide channel 62a.In addition, pedestal 4a more can cover plate 7 in conjunction with one, is covered on the first working face 41a in order to cover direction III along one, and the operational and controlled key button 45 of protection electronic installation 200a.In addition, in the present embodiment, slide electronic device 200a is a sliding cover type mobile phone.
By the above-mentioned embodiment of the invention as can be known, the present invention really has the value on the industry.But above embodiment explanation only is preferred embodiment explanation of the present invention, all habit in this operator when doing other all improvement and variation according to the above embodiment of the present invention explanation.Yet all improvement and variation that these are done according to the embodiment of the invention are in the claim that still belongs to invention spirit of the present invention and define.

Claims (14)

1. magnetic force assistant slide locating mechanism comprises:
One first platform comprises:
One two-sided tooth bar; And
2 first magnet are located at two ends of this two-sided tooth bar respectively, and this first magnet possesses one first magnetic pole and one second magnetic pole, and first magnetic pole of above-mentioned 2 first magnet disposes toward each other; And
One second platform comprises:
Two magnetic gears are engaged in two sides of this two-sided tooth bar respectively, and possess this first magnetic pole and this second magnetic pole,
Wherein, when in the middle of above-mentioned two magnetic gears turn to this two-sided tooth bar, locating, this first magnetic pole of above-mentioned two magnetic gears is toward each other and mutually exclusive, and when turning to two ends of this two-sided tooth bar, this second magnetic pole of above-mentioned two magnetic gears is inhaled mutually with this first magnetic pole of this first magnet.
2. magnetic force assistant slide locating mechanism as claimed in claim 1, wherein, this first magnetic pole is the N utmost point, this second magnetic pole is the S utmost point.
3. magnetic force assistant slide locating mechanism as claimed in claim 1, wherein, two lateral margins of this first platform and this second platform more are combined with a slip arrangement for guiding, and this slip arrangement for guiding includes pair of guide rails and a pair of and this guide channel that guide rail is cooperated.
4. magnetic force assistant slide locating mechanism as claimed in claim 3, wherein, this lays respectively at two lateral margins of this first platform to guide channel, and this lays respectively at two lateral margins of this second platform to guide rail.
5. magnetic force assistant slide locating mechanism as claimed in claim 4, wherein, this lays respectively at two lateral margins of this second platform to guide channel, and this lays respectively at two lateral margins of this first platform to guide rail.
6. magnetic force assistant slide locating mechanism as claimed in claim 1, wherein, two above-mentioned magnetic gears are embedded with one second magnet more respectively.
7. magnetic force assistant slide locating mechanism as claimed in claim 1, wherein, this first platform tool has one first working face, this two-sided tooth bar and 2 first above-mentioned magnetic magnet, be incorporated into this first working face, this second platform tool has second working face towards this first working face, and above-mentioned two magnetic gears are articulated in this second working face.
8. slide electronic device with magnetic force assist location mechanism comprises:
One pedestal comprises:
One two-sided tooth bar; And
2 first magnet are located at two ends of this two-sided tooth bar respectively, and this first magnet possesses one first magnetic pole and one second magnetic pole, and first magnetic pole of above-mentioned 2 first magnet disposes toward each other; And
One slip lid comprises:
Two magnetic gears are engaged in two sides of this two-sided tooth bar respectively, and possess this first magnetic pole and this second magnetic pole,
Wherein, when in the middle of above-mentioned two magnetic gears turn to this two-sided tooth bar, locating, this first magnetic pole system of above-mentioned two magnetic gears is toward each other and mutually exclusive, and when turning to two ends of this two-sided tooth bar, this second magnetic pole of above-mentioned two magnetic gears is inhaled mutually with this first magnetic pole of this first magnet.
9. magnetic force assistant slide locating mechanism as claimed in claim 8, wherein, this first magnetic pole is the S utmost point, this second magnetic pole is the N utmost point.
10. magnetic force assistant slide locating mechanism as claimed in claim 8, wherein, two lateral margins of this pedestal and this slip lid more are combined with a slip arrangement for guiding, and this slip arrangement for guiding includes pair of guide rails and a pair of and this guide channel that guide rail is cooperated.
11. magnetic force assistant slide locating mechanism as claimed in claim 10, wherein, this lays respectively at two lateral margins of this pedestal to guide channel, and this lays respectively at two lateral margins of this slip lid to guide rail.
12. magnetic force assistant slide locating mechanism as claimed in claim 11, wherein, this lays respectively at two lateral margins of this slip lid to guide channel, and this lays respectively at two lateral margins of this pedestal to guide rail.
13. magnetic force assistant slide locating mechanism as claimed in claim 8, wherein, two above-mentioned magnetic gears are embedded with one second magnet more respectively.
14. magnetic force assistant slide locating mechanism as claimed in claim 8, wherein, this pedestal possesses one first working face is arranged, this two-sided tooth bar and 2 first above-mentioned magnetic magnet, be incorporated into this first working face, this pedestal possesses second working face towards this first working face is arranged, and above-mentioned two magnetic gears are articulated in this second working face.
CNA2006101686860A 2006-12-22 2006-12-22 Magnetic force assistant slide locating mechanism Pending CN101207985A (en)

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Application Number Priority Date Filing Date Title
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Application Number Priority Date Filing Date Title
CNA2006101686860A CN101207985A (en) 2006-12-22 2006-12-22 Magnetic force assistant slide locating mechanism

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CN101959379A (en) * 2009-07-16 2011-01-26 鸿富锦精密工业(深圳)有限公司 Electronic equipment and blocking device thereof
CN102148883A (en) * 2010-02-04 2011-08-10 瑞轩科技股份有限公司 Handheld device by using magnetic elements to realize automatic positioning
CN103885539A (en) * 2012-12-20 2014-06-25 华硕电脑股份有限公司 Electronic device
CN103885539B (en) * 2012-12-20 2017-03-01 华硕电脑股份有限公司 Electronic installation
CN103727200A (en) * 2014-01-10 2014-04-16 姚平 Mechanical motion magnetic force conversion device
CN103727200B (en) * 2014-01-10 2016-06-15 姚平 A kind of mechanical motion magnetic force conversion device
CN106062656A (en) * 2014-03-28 2016-10-26 英特尔公司 Adjustment of magnetic force in a computing device
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WO2020019523A1 (en) * 2018-07-27 2020-01-30 北京小米移动软件有限公司 Slide rail and mobile terminal
JP7250523B2 (en) 2018-07-27 2023-04-03 北京小米移動軟件有限公司 Slide rail and mobile terminal
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