CN207780466U - Laser projection module, depth camera and electronic device - Google Patents
Laser projection module, depth camera and electronic device Download PDFInfo
- Publication number
- CN207780466U CN207780466U CN201820278744.3U CN201820278744U CN207780466U CN 207780466 U CN207780466 U CN 207780466U CN 201820278744 U CN201820278744 U CN 201820278744U CN 207780466 U CN207780466 U CN 207780466U
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- Prior art keywords
- lens barrel
- convex block
- positioning region
- projection module
- laser projection
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- Lens Barrels (AREA)
Abstract
The utility model discloses a kind of laser projection modules.Laser projection module includes board unit, lens barrel, light source, collimating element and diffraction optical element.Lens barrel includes lens barrel side wall, and lens barrel side wall is arranged on board unit and host cavity is collectively formed with board unit, and lens barrel includes being formed with the first positioning region from the inwardly projecting limit protrusion of lens barrel side wall, lens barrel.Light source is disposed on the substrate and is used to emit laser to host cavity.Collimating element is housed in host cavity.Light source, collimating element and diffraction optical element are successively set in the light path of light source, diffraction optical element outer surface includes bottom surface, bottom surface is combined with limit protrusion, diffraction optical element includes the second positioning region for being formed in outer surface, when bottom surface is combined with limit protrusion, the first positioning region coordinates with the second positioning region.When not being that bottom surface is combined with limit protrusion, the first positioning region cannot correctly coordinate with the second positioning region, prevent anti-loaded.
Description
Technical field
The utility model is related to optics and electronic technology fields, more specifically, are related to a kind of laser projection module, depth
Camera and electronic device.
Background technology
The medial surface of the diffraction optical element (diffractive optical elements, DOE) of laser projection module
On be etched with specific lines, and the structure of the lateral surface opposite with medial surface and the structure of medial surface differ, and spread out in use
When penetrating optical element, medial surface needs to arrange in strict accordance with given requirements with position of the lateral surface in laser optical path, and is pacifying
When filling diffraction optical element, diffraction optical element is easy anti-loaded, causes laser projection module can not normal use.
Utility model content
A kind of laser projection module of the utility model embodiment offer, depth camera and electronic device.
The laser projection module of the utility model embodiment includes:
Board unit;
Lens barrel, the lens barrel include lens barrel side wall, the lens barrel side wall be arranged on the board unit and with the base
Host cavity is collectively formed in board group part, and the lens barrel includes from the inwardly projecting limit protrusion of the lens barrel side wall, the lens barrel
It is formed with the first positioning region;
Light source, the light source setting to the host cavity on the substrate and for emitting laser;
Collimating element, the collimating element are housed in the host cavity;With
Diffraction optical element, the light source, the collimating element and the diffraction optical element are successively set on the light
In the light path in source, the diffraction optical element outer surface includes bottom surface, and the bottom surface is combined with the limit protrusion, the diffraction
Optical element includes the second positioning region for being formed in the outer surface, is combined with the limit protrusion and if only if the bottom surface
When, first positioning region coordinates with second positioning region.
In some embodiments, the outer surface further includes the top surface opposite with the bottom surface, and the connection bottom surface
With the side of the top surface, first positioning region includes be formed in the limit protrusion and lens barrel side wall intersection the
One chamfering, second positioning region include the second chamfering for being formed in the bottom surface and the side intersection.
In some embodiments, the limit protrusion is formed with the confined planes combined with the bottom surface, and described first is fixed
Position portion includes the confined planes recess being formed on the confined planes, and second positioning region includes the bottom surface protruded from the bottom surface
Convex block, when the bottom surface is combined with the limit protrusion, the bottom surface convex block stretches into the confined planes recess.
In some embodiments, the limit protrusion is formed with the confined planes combined with the bottom surface, and described first is fixed
Position portion includes the confined planes convex block protruded from the confined planes, second positioning region include be formed in the bottom surface bottom surface it is recessed
It falls into, when the bottom surface is combined with the limit protrusion, the confined planes convex block stretches into the bottom surface recess.
In some embodiments, the outer surface further includes the top surface opposite with the bottom surface, and the connection bottom surface
With the side of the top surface, first positioning region includes the lens barrel recess for being formed in the lens barrel side wall, second positioning
Portion includes the side convex block outwardly protruded from the side, and when the bottom surface is combined with the limit protrusion, the side is convex
Block stretches into the lens barrel recess.
In some embodiments, the side includes the sub- side that multiple head and the tail connect successively, lens barrel recess with
The quantity of the side convex block is single, and the side convex block is formed in other positions except the centre position of the sub- side
It sets.
In some embodiments, lens barrel recess it is equal with the quantity of side convex block and be it is multiple, it is multiple
The lens barrel recess is corresponding with multiple side convex blocks, and the shape of each side convex block is recessed with the corresponding lens barrel
Shape it is identical, the shape of the different side convex blocks differs.
In some embodiments, the side includes the sub- side that multiple head and the tail connect successively, lens barrel recess with
The quantity of the side convex block is equal and is multiple, and multiple side convex blocks are not in relation in any one of sub- side
Between positional symmetry.
In some embodiments, lens barrel recess it is equal with the quantity of side convex block and be it is multiple, it is multiple
The non-equiangularly spaced distribution of side convex block.
In some embodiments, along the top surface to the direction of the bottom surface, the size of the side convex block gradually subtracts
Small, the size of the lens barrel recess is gradually reduced.
In some embodiments, the shape that the plane that the side convex block is parallel to the bottom surface intercepts be rectangle,
Semicircle, triangle, it is trapezoidal, round in any one or more.
In some embodiments, the outer surface further includes the top surface opposite with the bottom surface, and the connection bottom surface
With the side of the top surface, first positioning region includes the lens barrel convex block protruded from the lens barrel side wall, second positioning
Portion includes the side-facing depressions for being formed in the side, and when the bottom surface is combined with the limit protrusion, the lens barrel convex block is stretched
Enter in the side-facing depressions.
In some embodiments, along the top surface to the direction of the bottom surface, the size of the side-facing depressions gradually increases
Greatly, the size of the lens barrel convex block gradually increases.
The depth camera of the utility model embodiment includes:
Laser projection module described in any of the above-described embodiment;
Image acquisition device, described image collector project after the diffraction optical element into object space for acquiring
Laser pattern;With
The processor being connect respectively with the laser projection module and described image collector, the processor is for handling
The laser image is to obtain depth image.
The electronic device of the utility model embodiment includes:
Shell;With
Depth camera described in the above embodiment, the depth camera setting are in the shell and sudden and violent from the shell
Dew is to obtain depth image.
In the laser projection module of the utility model embodiment, depth camera and electronic device, due to the first positioning region
Only can correctly it coordinate when bottom surface is combined with limit protrusion with the second positioning region, when the cooperation of diffraction optical element and lens barrel is closed
System is not when being that preset bottom surface is combined with limit protrusion, the first positioning region and the second positioning region cannot correctly coordinate and it is easy by with
Family is perceived, and diffraction optical element setup error is prevented.
The additional aspect and advantage of the embodiment of the utility model will be set forth in part in the description, partly will be from
Become apparent in following description, or is recognized by the practice of the embodiment of the utility model.
Description of the drawings
In description of the above-mentioned and/or additional aspect and advantage of the utility model from combination following accompanying drawings to embodiment
It will be apparent and be readily appreciated that, wherein:
Fig. 1 is the structural schematic diagram of the electronic device of the utility model embodiment;
Fig. 2 is the structural schematic diagram of the depth camera of the utility model embodiment;
Fig. 3 is the stereoscopic schematic diagram of the laser projection module of the utility model embodiment;
Fig. 4 is the floor map of the laser projection module of the utility model embodiment;
Fig. 5 is the perspective exploded view figure of the laser projection module of the utility model embodiment;
Fig. 6 is schematic cross-section of the laser projection module shown in Fig. 4 along line VI -- VI;
Fig. 7 is showing along the section of laser projection module line VI -- VI as shown in fig. 4 for another embodiment of the utility model
It is intended to;
Fig. 8 is schematic cross-section of the laser projection module shown in Fig. 4 along VIII-VIII lines;
Fig. 9 is the enlarged diagram of the parts IX of the laser projection module in Fig. 8;
Figure 10 is the enlarged diagram of the X section of laser projection module shown in fig. 5;
Figure 11 is the stereoscopic schematic diagram of the protection cap of the laser projection module of the utility model embodiment;
Figure 12 is the part-structure schematic diagram of the laser projection module of the utility model embodiment;
Figure 13 is the part-structure schematic diagram of the laser projection module of the utility model embodiment;
Figure 14 is that the laser projection module of the utility model embodiment removes the floor map after protection cap;
Figure 15 is that the laser projection module of another embodiment of the utility model removes the floor map after protection cap;
Figure 16 is that the laser projection module of the utility model a further embodiment removes the floor map after protection cap;
Figure 17 is the structural schematic diagram of the diffraction optical element and lens barrel side wall of the utility model embodiment;
Figure 18 is that the laser projection module of the another embodiment of the utility model removes the floor map after protection cap;
Figure 19 is the structural schematic diagram of the diffraction optical element and lens barrel side wall of the another embodiment of the utility model.
Main element symbol description:
Electronic device 1000, shell 200, depth camera 100, laser projection module 10, board unit 11, substrate 111, electricity
Road plate 112, lens barrel 12, host cavity 121, lens barrel side wall 122, limit protrusion 123, crosses unthreaded hole 1231, confined planes at via 113
1232, the first face 124, the second face 125, glue groove 126, madial wall 1261, inner bottom wall 1262, the second hook 127, guide ramp
1271, the first positioning region 128, the first chamfering 1281, confined planes recess 1282, confined planes convex block 1283, lens barrel recess 1284, mirror
Cylinder convex block 1285, light source 13, collimating element 14, optical section 141, mounting portion 142, diffraction optical element 15, top surface 151, bottom surface
152, side 153, sub- side 1531, the second positioning region 154, the second chamfering 1541, bottom surface convex block 1542, bottom surface recess 1543,
Side convex block 1544, side-facing depressions 1545, protection cap 16, protection roof 161, light hole 1611, protective side wall 162, protection
Side wall 1621, dispensing hole 163, the first hook 164, avoid holes 165, connector 17, image acquisition device 20, processor 30, projection
Window 40, acquisition window 50.
Specific implementation mode
The embodiment of the utility model is described further below in conjunction with attached drawing.Same or similar label in attached drawing
Same or similar element or element with the same or similar functions are indicated from beginning to end.
In addition, the embodiment of the utility model described below in conjunction with the accompanying drawings is exemplary, it is only used for explaining this reality
With novel embodiment, and should not be understood as limiting the present invention.
In the present invention unless specifically defined or limited otherwise, fisrt feature is "above" or "below" second feature
Can be that the first and second features are in direct contact or the first and second features pass through intermediary mediate contact.Moreover, first is special
Sign second feature " on ", " top " and " above " can be fisrt feature and be directly above or diagonally above the second feature, or only
Indicate that fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " lower section " and " below " can be with
It is that fisrt feature is directly under or diagonally below the second feature, or is merely representative of fisrt feature level height and is less than second feature.
Referring to Fig. 1, the electronic device 1000 of the utility model embodiment includes shell 200 and depth camera 100.Electricity
Sub-device 1000 can be mobile phone, tablet computer, laptop computer, game machine, head aobvious equipment, access control system, automatic teller machine etc., this reality
It is illustrated so that electronic device 1000 is mobile phone as an example with new embodiment, it will be understood that the concrete form of electronic device 1000
Can be other, this is not restricted.The setting of depth camera 100 exposes in shell 200 and from shell 200 to obtain depth map
Picture, shell 200 can provide the protection of dust-proof, waterproof, shatter-resistant etc. to depth camera 100, be offered on shell 200 and depth phase
100 corresponding hole of machine, so that light is pierced by from hole or penetrates shell 200.
Referring to Fig. 2, depth camera 100 includes laser projection module 10, image acquisition device 20 and processor 30.Depth phase
It could be formed with projection window 40 corresponding with laser projection module 10, and acquisition corresponding with image acquisition device 20 on machine 100
Window 50.Laser projection module 10 is used to project laser pattern to object space by projecting window 40, and image acquisition device 20 is used
It is acquired by the modulated laser pattern of subject matter in by acquisition window 50.In one example, laser projection module 10 projects
Laser be infrared light, image acquisition device 20 be infrared camera.Processor 30 and laser projection module 10 and image acquisition device
20 are all connected with, and processor 30 is for handling laser pattern to obtain depth image.Specifically, processor 30 is calculated using images match
Method calculates the deviation value of each pixel corresponding with reference pattern of each pixel in the laser pattern, further according to the deviation
Value further obtains the depth image of the laser pattern.Wherein, image matching algorithm can be digital picture correlation (Digital
Image Correlation, DIC) algorithm.It is of course also possible to use other image matching algorithms replace DIC algorithms.Below will
The structure of laser projection module 10 is described further.
Please refer to Fig. 3 to Fig. 5, laser projection module 10 include board unit 11, lens barrel 12, light source 13, collimating element 14,
Diffraction optical element 15 and protection cap 16.Light source 13, collimating element 14 and diffraction optical element 15 are successively set on light source 13
In light path, specifically, the light that light source 13 is sent out sequentially passes through collimating element 14 and diffraction optical element 15.
Fig. 5 and Fig. 6 are please referred to, board unit 11 includes substrate 111 and the circuit board 112 being carried on substrate 111.Substrate
111 for carrying lens barrel 12, light source 13 and circuit board 112.The material of substrate 111 can be plastics, such as poly terephthalic acid
Glycol ester (Polyethylene Glycol Terephthalate, PET), polymethyl methacrylate (Polymethyl
Methacrylate, PMMA), makrolon (Polycarbonate, PC), in polyimides (Polyimide, PI) at least
It is a kind of.That is, the unitary plastic material that any one in PET, PMMA, PC or PI may be used in substrate 111 is made.Such as
This, 111 lighter weight of substrate and have enough support strengths.
Circuit board 112 can be any one in printed circuit board, flexible PCB, Rigid Flex.Circuit board 112
On can offer via 113, can be used for accommodating light source 13 in via 113, the part of circuit board 112 is covered by lens barrel 12,
Another part extends out and can be connect with connector 17, and laser projection module 10 can be connected to electronics dress by connector 17
It sets on 1000 mainboard.
Fig. 6 to Fig. 8 is please referred to, lens barrel 12 is arranged on board unit 11 and host cavity is collectively formed with board unit 11
121.Specifically, lens barrel 12 can be connect with the circuit board 112 of board unit 11, and lens barrel 12 can be by viscous with circuit board 112
Glue sticking, to improve the air-tightness of host cavity 121.Certainly, lens barrel 12 and the specific connection type of board unit 11 can have it
He, such as by being connected together.Host cavity 121 can be used for accommodating the components such as collimating element 14, diffraction optical element 15, receive
Vessel 121 is formed simultaneously a part for the light path of laser projection module 10.In the utility model embodiment, lens barrel 12 is in hollow
Tubular, lens barrel 12 include lens barrel side wall 122 and limit protrusion 123.
Lens barrel side wall 122 surrounds host cavity 121, and the outer wall of lens barrel side wall 122 could be formed with positioning and mounting structure, with
Convenient for the position of the fixed laser projection module 10 when laser projection module 10 to be mounted in electronic device 1000.Lens barrel 12 wraps
Opposite the first face 124 and the second face 125 are included, wherein the one of host cavity 121 is opened on the second face 125, another
It is opened on the first face 124.Second face 125 is combined with circuit board 112, such as glued, and the first face 124 can be used as lens barrel
12 and diffraction optical element 15 or protection cap 16 etc. faying face.Incorporated by reference to Fig. 9 and Figure 10, the outer wall of lens barrel side wall 122 opens up
There are glue groove 126, glue groove 126 that can open up from the first face 124 and extend to the direction in the second face 125.
Fig. 8 and Fig. 9 are please referred to, limit protrusion 123 is inwardly projecting from lens barrel side wall 122, and specifically, limit protrusion 123 is certainly
Lens barrel side wall 122 is prominent into host cavity 121.Limit protrusion 123 can be in that continuous cyclic annular or limit protrusion 123 includes
Multiple, multiple limit protrusions 123 are spaced apart.Limit protrusion 123 surrounded unthreaded hole 1231, and receiving can be used as by crossing unthreaded hole 1231
A part for chamber 121, laser penetrated diffraction optical element 15 after passing through unthreaded hole 1231.In the embodiment illustrated in fig. 6, it limits
For position protrusion 123 between the first face 124 and the second face 125, the host cavity 121 between limit protrusion 123 and the second face 125 can
For accommodating collimating element 14, the host cavity 121 between limit protrusion 123 and the first face 124 can be used for accommodating diffraction light
Learn element 15.Meanwhile when assembling laser projection module 10, when diffraction optical element 15 and limit protrusion 123 offset, it can recognize
It is installed in place for diffraction optical element 15, when collimating element 14 and limit protrusion 123 offset, it is believed that collimating element 14 is installed
In place.Limit protrusion 123 includes confined planes 1232, when diffraction optical element 15 is mounted on limit protrusion 123, confined planes
1232 are combined with diffraction optical element 15.
Referring to Fig. 8, light source 13 is arranged on board unit 11, specifically, light source 13 can be arranged on circuit board 112
And be electrically connected with circuit board 112, light source 13 can also be arranged it is on substrate 111 and corresponding with via 113, at this point it is possible to pass through
Light source 13 is electrically connected by arrangement conducting wire with circuit board 112.Light source 13 is for emitting laser, and laser can be infrared light, at one
In example, light source 13 may include the emitting laser of semiconductor substrate and setting on a semiconductor substrate, and semiconductor substrate is set
It sets on substrate 111, emitting laser can be vertical cavity surface emitting laser (Vertical Cavity Surface
Emitting Laser,VCSEL).Single emitting laser can be arranged in semiconductor substrate, can also be arranged and be swashed by multiple transmittings
The array laser of light device composition, specifically, multiple emitting lasers can be with the shape of regularly or irregularly two-dimensional pattern
Formula is arranged on a semiconductor substrate.
Referring to Fig. 8, collimating element 14 can be optical lens, collimating element 14 swashs for what collimated light source 13 emitted
Light, collimating element 14 are housed in host cavity 121, and collimating element 14 can be directed toward the direction group in the first face 124 along the second face 125
It is attached in host cavity 121.Collimating element 14 includes optical section 141 and mounting portion 142, and mounting portion 142 is used for and lens barrel side wall 122
In conjunction with and fixed collimating element 14, in the utility model embodiment, optical section 141 includes being located at 14 opposite both sides of collimating element
Two curved surfaces.
Fig. 8 and Fig. 9 are please referred to, diffraction optical element 15 is mounted on limit protrusion 123, specifically, diffraction optical element
15 are combined with confined planes 1232 to be mounted on limit protrusion 123.The outer surface of diffraction optical element 15 includes top surface 151, bottom
Face 152 and side 153.Top surface 151 and bottom surface 152 are opposite, and side 153 connects top surface 151 and bottom surface 152, when diffraction optics member
When part 15 is mounted on limit protrusion 123, bottom surface 152 is combined with confined planes 1232.In the utility model embodiment, bottom surface 152
On be formed with diffraction structure, top surface 151 can be smooth plane, and diffraction optical element 15 can collimate collimated element 14
Laser projection afterwards goes out laser pattern corresponding with diffraction structure.Diffraction optical element 15 can be made of glass, it may also be said to
It is made of composite plastic (such as PET).
Fig. 8 and Fig. 9 are please referred to, protection cap 16 is combined with lens barrel 12, and protection cap 16 is for diffraction-limited optical element 15
Position, specifically, protection cap 16 after preventing the combination of diffraction optical element 15 and lens barrel 12 from failing from lens barrel 12 for deviating from.
Incorporated by reference to Figure 11, protection cap 16 includes protection roof 161 and protective side wall 162.
Spread out in other words the opposite both sides that protection roof 161 is located at diffraction optical element 15 with limit protrusion 123
It penetrates optical element 15 to be located between limit protrusion 123 and protection roof 161, in this way, even if diffraction optical element 15 and limit convex
It plays 123 combination to fail, due to protecting the restriction effect of roof 161, diffraction optical element 15 will not deviate from.Protect roof
161 offer light hole 1611, and the position of light hole 1611 is corresponding with diffraction optical element 15, and laser successively passed through unthreaded hole
1231, it is projected from laser projection module 10 after diffraction optical element 15 and light hole 1611.In the utility model embodiment,
Protect the global shape of roof 161 rounded rectangular, light hole 1611 can rounded, rectangle, ellipse, the shapes such as trapezoidal.
In the embodiment illustrated in fig. 6, when protection cap 16 is combined with lens barrel 12, protection roof 161 offsets with the first face 124, into
One step, protection roof 161 can also be combined with the first face 124 by way of gluing etc..
Fig. 9 to Figure 11 is please referred to, the periphery of 162 self-shield roof 161 of protective side wall extends, and protection cap 16 is located at lens barrel
On 12, protective side wall 162 is fixedly connected with lens barrel side wall 122.Protective side wall 162 includes protection that multiple head and the tail connect successively
Side wall 1621, each protects sub- side wall 1621 to be fixedly connected with lens barrel side wall 122, and sub- side wall 1621 is each protected to be respectively formed on
There is dispensing hole 163.The position in dispensing hole 163 is corresponding with the position of glue groove 126, after protection cap 16 is located on lens barrel 12,
Can be after the dispensing into glue groove 126 of dispensing hole 163, glue curing, protective side wall 162 is fixedly connected with lens barrel side wall 122.
In one example, it each protects and offers single dispensing hole 163 on sub- side wall 1621, it is in another example, each to protect
Multiple dispensing holes 163, such as two, three, four etc. are offered on sub- side wall 1621, in the utility model embodiment, often
Opened up on the sub- side wall of a protection 1621 there are two dispensing hole 163, two dispensing holes 163 respectively with two insides of glue groove 126
Wall 1261 corresponds to, and convenient for user to the dispensing simultaneously of the both sides of glue groove 126, improves dispensing speed.Further, glue groove 126
Madial wall 1261 tilt connection glue groove 126 inner bottom wall 1262 and lens barrel side wall 122 outer wall, tilt connection refer to it is interior
Side wall 1261 and inner bottom wall 1262, the equal out of plumb of outer wall of madial wall 1261 and lens barrel side wall 122, when glue is injected into inside
When on wall 1261, under the guide function of madial wall 1261, glue is easy to flow to the centre position of glue groove 126, accelerates glue
Water fills the speed of glue groove 126.
To sum up, in the electronic device 1000 of the utility model embodiment, since protection cap 16 is combined with lens barrel 12, protection
The position of the protection roof 161 and limit protrusion 123 together diffraction-limited optical element 15 of lid 16, diffraction optical element 15 will not
It falls off along light direction, avoids laser without launching after diffraction optical element 15, protect user, improve safety.
Referring to Fig. 7, in some embodiments, limit protrusion 123 can also be formed in the top of lens barrel 12, specifically
The confined planes 1232 on ground, limit protrusion 123 can be overlapped with the first face 124, and diffraction optical element 15 is mounted on limit protrusion 123
When upper, diffraction optical element 15 is combined with the first face 124.At this point, protection roof 161 offsets with diffraction optical element 15, protect
Diffraction optical element 15 is clamped with limit protrusion 123 in roof 161 jointly.In this way, the structure of lens barrel 12 is simple, diffraction optical element
15 are easily mounted on limit protrusion 123.
Fig. 9 to Figure 11 is please referred to, in some embodiments, protection cap 16 further includes that self-shield side wall 162 is inwardly projecting
Elasticity the first hook 164, lens barrel 12 further includes the second hook 127 outwardly protruded from the inner bottom wall 1262 of glue groove 126,
When protection cap 16 is located on lens barrel 12, the first hook 164 is engaged with the second hook 127 is detached from lens barrel to limit protection cap 16
12。
Specifically, the first hook 164 is corresponding with the position of the second hook 127, is located on lens barrel 12 by protection cap 16
During, the first hook 164 and the second hook 127 offset and elastic deformation occur, after protection cap 16 is installed in place, first
Hook 164 and the second hook 127 are engaged, and can be with tactile feedback and " clatter " sound being engaged into place.In this way, protection cap 16
Combined with lens barrel 12 it is more reliable, can be first by the first hook 164 and the and before being bonded protection cap 16 and lens barrel 12 with glue
Two hooks 127 are engaged, and the relative position of protection cap 16 and lens barrel 12 can be effectively fixed, and are conducive to progress for dispensing glue.
Fig. 9 to Figure 11 is please referred to, in some embodiments, sub- side wall 1621 is each protected to be respectively formed on the first hook
164.It is corresponding, the second hook 127, the position of the second hook 127 and the first hook 164 are also both provided in multiple glue grooves 126
Correspondence is set, multiple first hooks 164 are engaged simultaneously with corresponding second hook 127, and the combination of protection cap 16 and lens barrel 12 more may be used
It leans on.Specifically, the first hook 164 can be corresponding with the centre position of sub- side wall 1621 is protected, and the second hook 127 can be with appearance glue
The centre position of slot 126 corresponds to.When the sub- side wall of each protection 1621 is formed at least two dispensing holes 163, the first hook 164
Between at least two dispensing holes 163, more specifically, each protecting at least two dispensing holes, 163 phase on sub- side wall 1621
It is symmetrical for the first hook 164.In this way, being flowed respectively in the both sides of the first hook 164 and the second hook 127 convenient for glue
It is dynamic, and the glue quantity of both sides is suitable, cohesive force is more uniform.
Fig. 9 and Figure 11 are please referred to, in some embodiments, protective side wall 162 is in position corresponding with the first hook 164
Offer avoid holes 165.During protection cap 16 is located at lens barrel 12, the first hook 164 and the second hook 127 offset and
When elastic deformation occurs for the first hook 164, avoid holes 165 provide deformation space for the elastic deformation of the first hook 164, that is, the
One hook 164 occurs elastic deformation and stretches into avoid holes 165.Specifically, when the first hook 164 and the second hook 127 offset, the
Elastic deformation occurs outward for one hook 164, and the first hook 164 stretches into avoid holes 165 and moved to avoid with protective side wall 162
Interference, in addition, the mated condition that user observes the first hook 164 and the second hook 127 by avoid holes 165 is also allowed for, such as
Judge whether the first all hooks 164 is good with the occlusion of corresponding second hook 127.
Fig. 9 and Figure 10 are please referred to, in some embodiments, the second hook 127 is formed with guide ramp 1271, along protection
Lid 16 is inserted in the direction of lens barrel 12, and guide ramp 1271 is far from inner bottom wall 1262, during protection cap 16 is located at lens barrel 12,
First hook 164 offsets with guide ramp 1271.Since guide ramp 1271 is tilted relative to inner bottom wall 1262, the first hook
164 and second hook 127 coordinate during, the resist force for the second hook 127 that the first hook 164 is subject to slowly continuously increases
Greatly, the deformation quantity of the first hook 164 also continuously becomes larger, and the first hook 164 is easy to engage with the second hook 127.
Referring to Fig. 9, in some embodiments, the first positioning region 128, diffraction optical element 15 are formed on lens barrel 12
Outer surface on be formed with the second positioning region 154, and if only if the bottom surface of diffraction optical element 15 152 and 123 knot of limit protrusion
When conjunction, the first positioning region 128 and the second positioning region 154 coordinate.It is appreciated that the bottom surface 152 and top surface of diffraction optical element 15
151 structure is different, and bottom surface 152 also differs the effect of laser with top surface 151, when in use, if by diffraction optics member
Part 15 is anti-loaded (top surface 151 is combined with limit protrusion 123), and diffraction optical element 15 goes out the laser pattern of needs by diffraction is unable to,
Laser is even also resulted in concentrate transmitting and be easy the user that burns.First positioning region 128 of present embodiment and the second positioning region
154 only can correctly coordinate when bottom surface 152 is combined with limit protrusion 123, and matching when diffraction optical element 15 and lens barrel 12
When conjunction relationship is not that bottom surface 152 is combined with the confined planes 1232 of limit protrusion 123, the first positioning region 128 and the second positioning region 154
Cannot correctly it coordinate and user is readily appreciated that.In this way, preventing 15 setup error of diffraction optical element.
Referring to Fig. 9, in some embodiments, the first positioning region 128 includes the first chamfering 1281, the first chamfering 1281
It is formed in limit protrusion 123 and 122 intersection of lens barrel side wall, specifically, the first chamfering 1281 is formed in confined planes 1232 and mirror
122 intersection of cylinder side wall.Second positioning region 154 includes the second chamfering 1541, and the second chamfering 1541 is formed in diffraction optical element
15 bottom surface 152 and 153 intersection of side.First chamfering 1281 with the angle of inclination of the second chamfering 1541 can be it is equal,
If being appreciated that user is anti-loaded by diffraction optical element 15, top surface 151 will offset with the second chamfering 1541, lead to diffraction light
Element 15 is padded by the second chamfering 1541, and user is readily appreciated that diffraction optical element 15 is anti-loaded, therefore the first chamfering 1281
It can be anti-loaded to avoid diffraction optical element 15 with the second chamfering 1541.
Please refer to Fig.1 2, in certain embodiments, the first positioning region 128 includes the confined planes being formed on confined planes 1232
Recess 1282, the second positioning region 154 includes the bottom surface convex block 1542 protruded from bottom surface 152, when bottom surface 152 and limit protrusion 123
In conjunction with when, bottom surface convex block 1542 stretch into confined planes recess 1282 in.Specifically, bottom surface convex block 1542 and confined planes recess 1282
Position corresponds to, and bottom surface convex block 1542 is equal with the quantity of confined planes recess 1282, and the shape of bottom surface convex block 1542 can be round
Column, round table-like, prism-shaped etc., it will be understood that if user is anti-loaded by diffraction optical element 15, bottom surface 152 is upward and bottom surface
Out-of-flatness after convex block 1542 makes diffraction optical element 15 install, user are readily appreciated that diffraction optical element 15 is anti-loaded, therefore
Bottom surface convex block 1542 can be anti-loaded to avoid diffraction optical element 15 with confined planes recess 1282.
3 are please referred to Fig.1, in some embodiments, the first positioning region 128 includes the confined planes protruded from confined planes 1232
Convex block 1283, the second positioning region 154 includes the bottom surface recess 1543 for being formed in bottom surface 152, when bottom surface 152 and limit protrusion 123
In conjunction with when, confined planes convex block 1283 stretch into bottom surface recess 1543 in.Specifically, confined planes convex block 1283 and bottom surface recess 1543
Position corresponds to, and confined planes convex block 1283 is equal with the quantity of bottom surface recess 1543, and the shape of confined planes convex block 1283 can be
Cylindric, round table-like, prism-shaped etc., it will be understood that if user is anti-loaded by diffraction optical element 15, confined planes convex block 1283 will
It offsets with bottom surface 152, causing diffraction optical element 15 to be limited, face convex block 1283 is padded, and user is readily appreciated that diffraction optics member
Part 15 is anti-loaded, therefore confined planes convex block 1283 can be anti-loaded to avoid diffraction optical element 15 with bottom surface recess 1543.
4 are please referred to Fig.1, in some embodiments, the first positioning region 128 includes the lens barrel for being formed in lens barrel side wall 122
Recess 1284, the second positioning region 154 include the side convex block 1544 that the side 153 of self-diffraction optical element 15 outwardly protrudes, when
When bottom surface 152 is combined with limit protrusion 123, side convex block 1544 stretches into lens barrel recess 1284.Side convex block 1544 and lens barrel
The position of recess 1284 corresponds to, and side convex block 1544 is equal with the quantity of lens barrel recess 1284, and side convex block 1544 is parallel
In the shape that the plane of bottom surface 152 intercepts can be rectangle, semicircle, triangle, it is trapezoidal, round in it is one or more.It can
To understand, if user is anti-loaded by diffraction optical element 15, side convex block 1544 will offset with lens barrel side wall 122, lead to diffraction
Optical element 15 can not be mounted on limit protrusion 123, and user is readily appreciated that diffraction optical element 15 is anti-loaded, therefore side is convex
Block 1544 can be anti-loaded to avoid diffraction optical element 15 with lens barrel recess 1284.
Specifically, 4 are please referred to Fig.1, in some embodiments, side 153 includes the sub- side that multiple head and the tail connect successively
Face 1531, lens barrel recess 1284 and the quantity of side convex block 1544 are single.Side convex block 1544 is formed in sub- side 1531
Centre position except other positions.That is, when the quantity of side convex block 1544 is one, side convex block 1544 can
With the other positions being opened in except 1531 centre position of sub- side, when preventing user that diffraction optical element 15 is anti-loaded, side
Convex block 1544 still can extend into lens barrel recess 1284 the case where occur, it is anti-loaded to further avoid diffraction optical element 15.
5 are please referred to Fig.1, in some embodiments, lens barrel recess 1284 is equal and equal with the quantity of side convex block 1544
To be multiple, multiple lens barrels recess 1284 is corresponding with multiple side convex blocks 1544, the shape of each side convex block 1544 with it is corresponding
The shape of lens barrel recess 1284 is identical, and the shape of different side convex blocks 1544 differs.Side convex block 1544 is recessed with lens barrel
The identical outer profile for referring to side convex block 1544 of 1284 shape is identical as the hollow shape of lens barrel recess 1284.This implementation
In example, since the shape of different side convex blocks 1544 differs, not mutual corresponding side convex block 1544 is recessed with lens barrel
1284 cannot be fully mated since shape is different, and user is easy to discover whether diffraction optical element 15 is correctly installed.
6 are please referred to Fig.1, in some embodiments, side 153 includes the sub- side 1531 that multiple head and the tail connect successively,
Lens barrel recess 1284 is equal with the quantity of side convex block 1544 and is multiple, and multiple side convex blocks 1544 are not in relation to any one
The centre position of sub- side 1531 is symmetrical.In embodiment as shown in figure 16, diffraction optical element 15 is whole to be square, side
153 include four sub- sides 1531, and the quantity of side convex block 1544 is two and is respectively positioned on a sub- side 1531, two sides
The centre position that face convex block 1544 is not in relation to any one sub- side 1531 is symmetrical.Certainly, side convex block 1544 is in certain sub- side
Quantity on face 1531 can also be one, and side convex block 1544 is also distributed on other sub- sides 1531, but multiple
The centre position that side convex block 1544 is not in relation to any one sub- side 1531 is symmetrical.In this way, when user is intended to diffraction optics member
When part 15 turns installation, at least one side convex block 1544 can offset with lens barrel side wall 122, and user is readily appreciated that diffraction optics
Element 15 is anti-loaded.
6 are please referred to Fig.1, in some embodiments, lens barrel recess 1284 is equal and equal with the quantity of side convex block 1544
To be multiple, multiple non-equiangularly spaced distributions of side convex block 1544.Specifically, when the quantity of side convex block 1544 is two,
Two side convex blocks 1544 are not in respectively 180 degree with the angle of the line at the center of diffraction optical element 15;When side is convex
The quantity of block 1544 be three when, adjacent two side convex blocks 1544 respectively with the line at the center of diffraction optical element 15
Angle is not all in 120 degree.In this way, when user is intended to diffraction optical element 15 turning installation, at least one side is convex
Block 1544 can offset with lens barrel side wall 122, and user is readily appreciated that diffraction optical element 15 is anti-loaded.
7 are please referred to Fig.1, in some embodiments, the direction along top surface 151 to bottom surface 152, the ruler of side convex block 1544
Very little to be gradually reduced, the size of lens barrel recess 1284 is gradually reduced.Further, the full-size of side convex block 1544 is more than lens barrel
The minimum dimension of recess 1284, when user is intended to diffraction optical element 15 turning installation, side convex block 1544 cannot be stretched completely
Enter in lens barrel recess 1284, side convex block 1544 can be padded by diffraction optical element 15, and user is readily appreciated that diffraction optics member
Part 15 is anti-loaded.
8 are please referred to Fig.1, in some embodiments, the first positioning region 128 includes the lens barrel protruded from lens barrel side wall 122
Convex block 1285, the second positioning region 154 includes the side-facing depressions 1545 for being formed in side 153, when bottom surface 152 and limit protrusion 123
In conjunction with when, lens barrel convex block 1285 stretches into side-facing depressions 1545.Lens barrel convex block 1285 is corresponding with the position of side-facing depressions 1545, and
Lens barrel convex block 1285 is equal with the quantity of side-facing depressions 1545, and lens barrel convex block 1285 is parallel to what the plane of bottom surface 152 intercepted
Shape can be rectangle, semicircle, triangle, it is trapezoidal, round in it is one or more.If being appreciated that user by diffraction
Optical element 15 is anti-loaded, and lens barrel convex block 1285 will offset with diffraction optical element 15, cause diffraction optical element 15 that can not install
On limit protrusion 123, user is readily appreciated that diffraction optical element 15 is anti-loaded, therefore lens barrel convex block 1285 and side-facing depressions
1545 can be anti-loaded to avoid diffraction optical element 15.
9 are please referred to Fig.1, in some embodiments, the direction along top surface 151 to bottom surface 152, the ruler of side-facing depressions 1545
Very little gradual increase, the size of lens barrel convex block 1285 gradually increase.Further, the full-size of lens barrel convex block 1285 is more than side
The minimum dimension of recess 1545, when user is intended to diffraction optical element 15 turning installation, lens barrel convex block 1285 cannot be stretched completely
Enter in lens barrel recess 1284, lens barrel convex block 1285 can be padded by diffraction optical element 15, and user is readily appreciated that diffraction optics member
Part 15 is anti-loaded.
In the description of this specification, reference term " certain embodiments ", " embodiment ", " some embodiment party
The description of formula ", " exemplary embodiment ", " example ", " specific example " or " some examples " means in conjunction with the embodiment
Or example particular features, structures, materials, or characteristics described are contained at least one embodiment of the utility model or show
In example.In the present specification, schematic expression of the above terms are not necessarily referring to identical embodiment or example.And
And particular features, structures, materials, or characteristics described can be in any one or more embodiments or example to close
Suitable mode combines.
In addition, term " first ", " second " are used for description purposes only, it is not understood to indicate or imply relative importance
Or implicitly indicate the quantity of indicated technical characteristic.Define " first " as a result, the feature of " second " can be expressed or
Implicitly include at least one feature.The meaning of " plurality " is at least two, such as two in the description of the present invention,
It is a, three, unless otherwise specifically defined.
Although the embodiments of the present invention have been shown and described above, it is to be understood that above-described embodiment is
Illustratively, it should not be understood as limiting the present invention, those skilled in the art are in the scope of the utility model
It inside can make changes, modifications, alterations, and variations to the above described embodiments, the scope of the utility model is by claim and its is equal
Object limits.
Claims (15)
1. a kind of laser projection module, which is characterized in that including:
Board unit;
Lens barrel, the lens barrel include lens barrel side wall, the lens barrel side wall be arranged on the board unit and with the substrate in batch
Host cavity is collectively formed in part, and the lens barrel includes being formed from the inwardly projecting limit protrusion of the lens barrel side wall, the lens barrel
There is the first positioning region;
Light source, the light source setting to the host cavity on the substrate and for emitting laser;
Collimating element, the collimating element are housed in the host cavity;With
Diffraction optical element, the light source, the collimating element and the diffraction optical element are successively set on the light source
In light path, the diffraction optical element outer surface includes bottom surface, and the bottom surface is combined with the limit protrusion, the diffraction optics
Element includes the second positioning region for being formed in the outer surface, when the bottom surface is combined with the limit protrusion, institute
The first positioning region is stated with second positioning region to coordinate.
2. laser projection module according to claim 1, which is characterized in that the outer surface further includes and the bottom surface phase
The top surface of the back of the body, and the side of the bottom surface and the top surface is connected, first positioning region includes being formed in the limit protrusion
With the first chamfering of lens barrel side wall intersection, second positioning region includes being formed in the bottom surface with the side to intersect
Second chamfering at place.
3. laser projection module according to claim 1, which is characterized in that the limit protrusion is formed with and the bottom surface
In conjunction with confined planes, first positioning region include be formed on the confined planes confined planes recess, second positioning region
Include the bottom surface convex block protruded from the bottom surface, when the bottom surface is combined with the limit protrusion, the bottom surface convex block stretches into
In the confined planes recess.
4. laser projection module according to claim 1, which is characterized in that the limit protrusion is formed with and the bottom surface
In conjunction with confined planes, first positioning region includes the confined planes convex block protruded from the confined planes, second positioning region packet
The bottom surface recess for being formed in the bottom surface is included, when the bottom surface is combined with the limit protrusion, the confined planes convex block stretches into
In the bottom surface recess.
5. laser projection module according to claim 1, which is characterized in that the outer surface further includes and the bottom surface phase
The top surface of the back of the body, and the side of the bottom surface and the top surface is connected, first positioning region includes being formed in the lens barrel side wall
Lens barrel recess, second positioning region includes the side convex block outwardly protruded from the side, when the bottom surface and the limit
When position protrusion combines, the side convex block stretches into the lens barrel recess.
6. laser projection module according to claim 5, which is characterized in that the side includes that multiple head and the tail connect successively
Sub- side, lens barrel recess and the quantity of the side convex block are single, and the side convex block is formed in the sub- side
Other positions except the centre position in face.
7. laser projection module according to claim 5, which is characterized in that the lens barrel recess and the side convex block
Quantity is equal and is multiple, and multiple lens barrel recess are corresponding with multiple side convex blocks, each side convex block
Shape is identical as the corresponding shape of lens barrel recess, and the shape of the different side convex blocks differs.
8. laser projection module according to claim 5, which is characterized in that the side includes that multiple head and the tail connect successively
Sub- side, lens barrel recess is equal with the quantity of side convex block and is multiple, and multiple side convex blocks are not related to
Centre position in any one of sub- side is symmetrical.
9. laser projection module according to claim 5, which is characterized in that the lens barrel recess and the side convex block
Quantity is equal and is multiple, multiple non-equiangularly spaced distributions of side convex block.
10. laser projection module according to claim 5, which is characterized in that along the top surface to the direction of the bottom surface,
The size of the side convex block is gradually reduced, and the size of the lens barrel recess is gradually reduced.
11. laser projection module according to claim 5, which is characterized in that the side convex block is parallel to the bottom
The shape that the plane in face intercepts be rectangle, semicircle, triangle, it is trapezoidal, round in any one or more.
12. laser projection module according to claim 1, which is characterized in that the outer surface further includes and the bottom surface
Opposite top surface, and the side of the bottom surface and the top surface is connected, first positioning region includes convex from the lens barrel side wall
The lens barrel convex block gone out, second positioning region includes the side-facing depressions for being formed in the side, when the bottom surface and the limit
When protrusion combines, the lens barrel convex block stretches into the side-facing depressions.
13. laser projection module according to claim 12, which is characterized in that along the top surface to the side of the bottom surface
To the size of the side-facing depressions gradually increases, and the size of the lens barrel convex block gradually increases.
14. a kind of depth camera, which is characterized in that including:
Laser projection module described in claim 1-13 any one;
Image acquisition device, described image collector be used to acquire projected into object space after the diffraction optical element it is sharp
Light pattern;With
The processor being connect respectively with the laser projection module and described image collector, the processor are described for handling
Laser image is to obtain depth image.
15. a kind of electronic device, which is characterized in that including:
Shell;With
Depth camera described in claim 14, the depth camera are arranged in the shell and are exposed from the shell to obtain
Take depth image.
Priority Applications (2)
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CN201820278744.3U CN207780466U (en) | 2018-02-27 | 2018-02-27 | Laser projection module, depth camera and electronic device |
PCT/CN2019/070770 WO2019165853A1 (en) | 2018-02-27 | 2019-01-08 | Laser projection module, depth camera and electronic device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN201820278744.3U CN207780466U (en) | 2018-02-27 | 2018-02-27 | Laser projection module, depth camera and electronic device |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108344375A (en) * | 2018-02-27 | 2018-07-31 | 广东欧珀移动通信有限公司 | Laser projection module, depth camera and electronic device |
WO2019165853A1 (en) * | 2018-02-27 | 2019-09-06 | Oppo广东移动通信有限公司 | Laser projection module, depth camera and electronic device |
-
2018
- 2018-02-27 CN CN201820278744.3U patent/CN207780466U/en not_active Expired - Fee Related
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108344375A (en) * | 2018-02-27 | 2018-07-31 | 广东欧珀移动通信有限公司 | Laser projection module, depth camera and electronic device |
WO2019165853A1 (en) * | 2018-02-27 | 2019-09-06 | Oppo广东移动通信有限公司 | Laser projection module, depth camera and electronic device |
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CP01 | Change in the name or title of a patent holder |
Address after: Changan town in Guangdong province Dongguan 523860 usha Beach Road No. 18 Patentee after: GUANGDONG OPPO MOBILE TELECOMMUNICATIONS Corp.,Ltd. Address before: Changan town in Guangdong province Dongguan 523860 usha Beach Road No. 18 Patentee before: GUANGDONG OPPO MOBILE TELECOMMUNICATIONS Corp.,Ltd. |
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Granted publication date: 20180828 |