CN112305700B - Projection lens and laser projection device - Google Patents

Abstract

The invention discloses a projection lens and a laser projection device, and belongs to the field of optical equipment. The projection lens comprises a base, and a refraction lens group and a reflection lens group which are sequentially arranged in the base along the light ray emergence direction, wherein the refraction lens group comprises a lens cone, and a first lens group, a second lens group and a third lens group which are sequentially arranged in the lens cone along the light ray emergence direction, wherein the first lens group is connected with the main lens cone through a curve cylinder and can move relative to the main lens cone when the curve cylinder rotates; the second lens group is connected with the main lens cone through the focusing structure and can move relative to the main lens cone under the action of the focusing structure, so that the first lens group and the second lens group can be moved according to various parameters of a picture to be projected, and the projected picture meets requirements. The problem that the projection lens in the related art is difficult to meet the requirements of various projection parameters is solved. The applicability of the projection lens is improved, and the projection lens can be suitable for various projection parameters.

Description

Projection lens and laser projection device

Technical Field

The present invention relates to the field of optical devices, and in particular, to a projection lens and a laser projection apparatus.

Background

With the improvement of scientific technology, the application of the projection lens in the work and life of people is more and more extensive, such as education, office, household or entertainment, for example, for the projection lens used in a home theater, the higher the resolution of the projection lens is, the higher the user viewing experience is. Therefore, the demand for projection lenses is also increasing.

In the related art, a laser projection apparatus includes: a light valve, a refractive lens group and a reflector; the light refracting lens group comprises a lens cone and a plurality of refracting lenses, and the refracting lenses are fixedly arranged at the preset positions in the lens cone.

In the process of implementing the invention, the inventor finds that the related art has at least the following problems: the projection lens is difficult to adapt to various projection parameters (such as resolution, size and the like).

Disclosure of Invention

The embodiment of the invention provides a projection lens and a laser projection device, which can solve the problem that the projection lens in the related art is difficult to adapt to requirements of various projection parameters. The technical scheme is as follows:

according to an aspect of the present invention, there is provided a projection lens, comprising a base, and a refractive lens group and a reflective lens group located in the base;

the refractor group comprises a lens cone and a first lens group, a second lens group and a third lens group which are sequentially arranged in the lens cone along the direction close to the reflector group;

the lens cone comprises a main lens cone and a curve cylinder sleeved outside the main lens cone, the first lens group is connected with the main lens cone through the curve cylinder, and the main lens cone is fixedly connected with the base;

the lens cone comprises a focusing structure, and the second lens group is connected with the main lens cone through the focusing structure;

the third lens group is fixedly connected with the main lens cone.

Optionally, the lens barrel further comprises a first lens barrel and at least one first adjusting mechanism, the first lens group is located in the first lens barrel;

the curve cylinder is sleeved outside the main lens barrel, the main lens barrel is sleeved outside the first lens barrel, and the axes of the curve cylinder, the main lens barrel and the first lens barrel are parallel to each other;

each first adjusting mechanism comprises a first strip-shaped groove and a second strip-shaped groove which are positioned on the wall of the curve barrel, the length direction of the first strip-shaped groove is perpendicular to the optical axis of the projection lens, and the length direction of the second strip-shaped groove is not perpendicular to the optical axis;

each first adjusting mechanism comprises a first terminal positioned on the cylinder wall of the main lens barrel, the first terminal is fixedly connected with the cylinder wall of the main lens barrel and matched with the first strip-shaped groove, and can move along the length direction of the first strip-shaped groove relative to the curve cylinder when the curve cylinder rotates by taking the axis of the curve cylinder as a shaft;

each first adjusting mechanism comprises a second terminal located on the cylinder wall of the first lens barrel, the second terminal is fixedly connected with the cylinder wall of the first lens barrel, each first adjusting mechanism comprises a strip-shaped through hole located on the cylinder wall of the main lens barrel, the length direction of the strip-shaped through hole is parallel to the optical axis, the second terminal penetrates through the strip-shaped through hole to be matched with a second strip-shaped groove on the curve cylinder, and the second terminal can move along the length direction of the second strip-shaped groove relative to the curve cylinder when the curve cylinder rotates by taking the axis of the curve cylinder as an axis.

Optionally, the lens barrel includes a second lens barrel, the focusing structure includes at least one second adjusting mechanism, the main lens barrel is sleeved outside the second lens barrel, and an axis of the second lens barrel is parallel to an axis of the main lens barrel;

each second adjusting mechanism comprises a third strip-shaped groove positioned on the cylinder wall of the main lens barrel, and the length direction of the third strip-shaped groove is not perpendicular to the optical axis;

each second adjusting mechanism comprises a third terminal located on the cylinder wall of the second lens barrel, and the third terminal is matched with the third strip-shaped groove and can move in the third strip-shaped groove along the length direction of the third strip-shaped groove.

Optionally, the third strip-shaped groove penetrates through a barrel wall of the main barrel, and the third terminal extends from the third strip-shaped groove to the outside of the main barrel.

Optionally, the mirror group is movably connected to the base, and is capable of moving along the length direction of the optical axis to adjust the resolution of the projection lens.

Optionally, the base has at least two threaded holes, a fixing plate extends out of the main barrel, the fixing plate has at least two through holes, and the fixing plate is fixedly connected to the at least two threaded holes through the at least two through holes and the at least two screws.

Optionally, the base has at least two limiting rods, the fixing plate has at least two limiting holes, and when the main lens barrel is fixed on the base, the at least two limiting rods are inserted into the at least two limiting holes in a one-to-one correspondence manner.

Optionally, a first connecting plate extends out of the third lens barrel, a second connecting plate extends out of the main lens barrel, the first connecting plate and the second connecting plate are fixedly connected through at least four screws, and the at least four screws surround the third lens barrel.

Optionally, when the first lens group moves along the length direction of the optical axis of the projection lens under the adjustment of the curve cylinder, the resolution of the projection lens can be adjusted;

when the second lens group moves along the length direction of the optical axis of the projection lens under the adjustment of the focusing structure, the resolution of the projection lens can be adjusted.

According to another aspect of the present invention, there is provided a laser projection apparatus, which includes a light source, a light valve, a screen and the projection lens;

the light source is used for providing a laser beam to the light valve;

the light valve is used for modulating the laser beam provided by the light source and then emitting the laser beam to the projection lens;

the projection lens is used for imaging the laser beam provided by the light valve and then emitting the laser beam to a screen.

The technical scheme provided by the embodiment of the invention has the beneficial effects that at least:

the projection lens comprises a base, and a refraction lens group and a reflection lens group which are sequentially arranged in the base along the light emergent direction, wherein the refraction lens group comprises a lens cone, and a first lens group, a second lens group and a third lens group which are sequentially arranged in the lens cone along the light emergent direction, the first lens group is connected with a main lens cone through a curve cylinder and can move relative to the main lens cone when the curve cylinder rotates; the second lens group is connected with the main lens cone through the focusing structure and can move relative to the main lens cone under the action of the focusing structure, so that the first lens group and the second lens group can be moved according to various parameters of a picture to be projected, and the projected picture meets requirements. The problem that the projection lens in the related art is difficult to meet the requirements of various projection parameters is solved. The applicability of the projection lens is improved, and the projection lens can be suitable for various projection parameters.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a laser projection apparatus provided in an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a projection lens according to an embodiment of the present invention;

fig. 3 is a schematic cross-sectional view illustrating another projection lens according to an embodiment of the present invention;

FIG. 4 is a schematic perspective exploded view of the main barrel, the curved barrel and the third barrel of the projection lens shown in FIG. 2;

FIG. 5 is a top view of the projection lens shown in FIG. 2;

fig. 6 is an exploded view of the projection lens shown in fig. 2.

With the above figures, there are shown certain embodiments of the invention and will be described in more detail hereinafter. The drawings and written description are not intended to limit the scope of the inventive concepts in any manner, but rather to illustrate the inventive concepts to those skilled in the art by reference to specific embodiments.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

A projection lens in a laser projection apparatus generally includes a lens barrel and a plurality of lenses mounted in the lens barrel, and the plurality of lenses are generally fixed at specified positions in the lens barrel, which are determined by the design of the projection lens.

However, the inability to vary the position of each lens results in a relatively narrow range of applications for the projection lens, and may only be suitable for projecting small-sized projection screens, for example.

The embodiment of the application provides a projection lens, which can solve the problems existing in the related technology.

Fig. 1 is a schematic structural diagram of a laser projection apparatus according to an embodiment of the present invention. The laser projection apparatus includes a light source 11, a light valve 12, a screen 13, and a projection lens 20.

The light source 11 is used to provide a laser beam to the light valve 12.

The light valve 12 is used for modulating the laser beam provided by the light source 11 and then emitting the modulated laser beam to the projection lens 20.

The projection lens 20 is used for imaging the laser beam provided by the light valve 12 and then emitting the laser beam to the screen 13. The projection lens 20 may be any one of the projection lenses provided in the following embodiments of the present invention.

Fig. 2 is a schematic structural diagram of a projection lens according to an embodiment of the present invention, where the projection lens may be the projection lens 20 in the implementation environment shown in fig. 1, and the projection lens 20 includes a base 21, and a refractive lens group 22 and a reflective lens group 23 located in the base 21.

The refractive lens group 22 includes a lens barrel 221, and a first lens group 222, a second lens group 223 and a third lens group 224 sequentially disposed in the lens barrel 221 along a direction close to the reflective lens group 23.

The lens barrel 221 includes a main lens barrel a and a curved cylinder C sleeved outside the main lens barrel, the first lens group 222 is connected with the main lens barrel a through the curved cylinder C, and the main lens barrel a is fixedly connected with the base 21.

The lens barrel 221 includes a focusing structure 2211, and the second lens group 223 is connected to the main barrel a through the focusing structure 2211.

The third lens group 224 is fixedly connected with the main lens cone a.

To sum up, the projection lens provided in the embodiment of the present application includes a base, and a refractive lens group and a reflective lens group sequentially disposed in the base along a light exit direction, wherein the refractive lens group includes a lens barrel, and a first lens group, a second lens group, and a third lens group sequentially disposed in the lens barrel along the light exit direction, wherein the first lens group is connected to the main lens barrel through a curve barrel and can move relative to the main lens barrel when the curve barrel rotates; the second lens group is connected with the main lens cone through the focusing structure and can move relative to the main lens cone under the action of the focusing structure, so that the first lens group and the second lens group can be moved according to various parameters of a picture to be projected, and the projected picture can meet requirements. The problem that the projection lens in the related art is difficult to meet the requirements of various projection parameters is solved. The applicability of the projection lens is improved, and the projection lens can be suitable for various projection parameters.

Fig. 3 is a schematic cross-sectional structural view of another projection lens provided in an embodiment of the present invention (the cross section may be a plane defined by an optical axis z). The projection lens is adjusted somewhat on the basis of the projection lens shown in fig. 2.

Optionally, the lens barrel 221 includes a main barrel a and a third barrel B, the main barrel a is fixedly connected with the base 21, and the third barrel B is fixedly connected with the base 21.

The first lens group 222 is movably connected to the main barrel a, the second lens group 223 is movably connected to the main barrel a, and the third lens group 224 is fixedly connected to the third barrel B.

Optionally, the lens barrel 221 further includes a curved barrel C, a first lens barrel D and at least one first adjusting mechanism (not labeled in fig. 3), and the first lens group 222 is located in the first lens barrel D.

The curve cylinder C is sleeved outside the main lens barrel A, the main lens barrel A is sleeved outside the first lens barrel D, and the axes of the curve cylinder C, the main lens barrel A and the first lens barrel D are parallel to each other.

Optionally, the lens barrel 221 includes a second lens barrel E, the focusing mechanism includes at least one second adjusting mechanism (not labeled in fig. 3), the main lens barrel a is sleeved outside the second lens barrel E, and an axis of the second lens barrel E is parallel to an axis of the main lens barrel a.

Alternatively, the mirror group 23 is movably connected to the base 21 so as to be movable in the longitudinal direction of the optical axis z.

Optionally, the third barrel B is fixedly connected with the main barrel a.

Fig. 3 shows a specific structure of each lens in the projection lens, but the embodiment of the invention does not limit this. The adjustment of the first lens group 222 along the length direction of the optical axis z can adjust the back focal length (i.e. the distance between the first lens group and the light valve), and the adjustment can include adjusting the resolution of the whole image.

Adjusting the second lens group 223 along the length direction of the optical axis z may include adjusting the resolution of the upper left and right corners of the picture, and slightly adjusting the overall distortion of the picture, such as adjusting a barrel-shaped picture into a rectangular picture.

The effect of adjusting the mirror group 223 along the length of the optical axis z may include adjusting the overall distortion and resolution of the picture. Wherein, the forward movement (making the reflector move along the direction close to the refractor set) of the reflector set can compensate the image resolution of the projection lens when the projection image size is 70-100 inches, and the backward movement (making the reflector move along the direction far from the refractor set) of the reflector set can compensate the image resolution of the projection lens when the projection image size is 60-100 inches.

In one adjustment mode, the reflector sets are pre-adjusted to the theoretical design position with the frame of the picture being positive and without barrel and pillow distortion, and then the first and second mirror sets are adjusted.

Fig. 4 is a schematic perspective exploded view of the main barrel a, the curve barrel C and the third barrel B of the projection lens shown in fig. 2.

Each first adjusting mechanism comprises a first strip-shaped groove C1 and a second strip-shaped groove C2 which are positioned on the wall of the curve cylinder C, the length direction of the first strip-shaped groove C1 is perpendicular to the optical axis z of the projection lens, and the length direction of the second strip-shaped groove C2 is not perpendicular to the optical axis z.

Each first adjusting mechanism comprises a first terminal a1 positioned on the cylinder wall of the main lens barrel a, and a first terminal a1 is fixedly connected with the cylinder wall of the main lens barrel a and is matched with a first linear groove C1, so that when the curve cylinder C rotates by taking the axis of the curve cylinder C (the axis can be coincident with or parallel to the optical axis z) as an axis, the curve cylinder C can move along the length direction of the first linear groove C1 relative to the curve cylinder C.

Each first adjusting mechanism comprises a second terminal D1 positioned on the cylinder wall of the first lens barrel D, the second terminal D1 is fixedly connected with the cylinder wall of the first lens barrel D, each first adjusting mechanism comprises a strip-shaped through hole (not shown in fig. 4) positioned on the cylinder wall of the main lens barrel a, the length direction of the strip-shaped through hole is parallel to the optical axis z, the second terminal D1 penetrates through the strip-shaped through hole to be matched with a second strip-shaped groove C2 on the curve cylinder C, and the second terminal D1 can move along the length direction of the second strip-shaped groove C2 relative to the curve cylinder C when the curve cylinder C rotates around the axis of the curve cylinder C (the axis can be coincident with or parallel to the optical axis z).

Optionally, a first connecting plate B1 extends from the outside of the third barrel B, a second connecting plate extends from the outside of the main barrel a, the first connecting plate B1 and the second connecting plate are fixedly connected by at least four screws, and the at least four screws surround the third barrel B.

Alternatively, the number of the first adjustment mechanisms may be 3, and 3 first adjustment mechanisms may be evenly arranged around the optical axis z (i.e., one for every 120 degrees). Therefore, the stability of the first lens barrel in the moving process can be improved.

Each second adjusting mechanism comprises a third strip-shaped groove a3 positioned on the barrel wall of the main lens barrel A, and the length direction of the third strip-shaped groove a3 and the optical axis z form a second specified included angle.

Each second adjustment mechanism includes a third terminal e1 located on the barrel wall of the second barrel (not shown in fig. 4), and the third terminal e1 is engaged with the third groove a3 and can move in the third groove a3 along the length direction of the third groove a 3.

Alternatively, the third strip-shaped groove a3 penetrates through the barrel wall of the main barrel a, and the third terminal e1 extends from the third strip-shaped groove a3 to the outside of the main barrel a. This facilitates adjustment of the third terminal e1 from outside the main barrel a. When the third groove a3 does not penetrate the barrel wall of the main barrel a, an adjustment mechanism may be provided inside the main barrel a to adjust the third terminal e 1.

Alternatively, the number of the second adjustment mechanisms may be 3, and 3 second adjustment mechanisms may be evenly arranged around the optical axis z (i.e., one every 120 degrees). Therefore, the stability of the second lens barrel in the moving process can be improved.

As shown in fig. 5, which is a top view of the projection lens shown in fig. 2. The base 21 has at least two threaded holes (not shown in fig. 5), a fixing plate a4 extends from the outside of the main barrel a, at least two through holes are formed in the fixing plate a4, and the fixing plate a4 is fixedly connected to the at least two threaded holes through the at least two through holes and the at least two screws t.

Optionally, the base 21 has at least two limiting rods F, the fixing plate a4 has at least two limiting holes (not marked in fig. 5), and when the main barrel a is fixed on the base 21, the at least two limiting rods F are inserted into the at least two limiting holes in a one-to-one correspondence.

The following describes the moving manner of the first lens group D according to fig. 5:

as can be seen from fig. 5, the length direction of the first stripe-shaped groove C1 on the curved tube C is perpendicular to the optical axis z, while the length direction of the second stripe-shaped groove C2 is not perpendicular to the optical axis z (i.e. the length direction of the second stripe-shaped groove C2 has an acute angle with the optical axis z). With such a structure, when the curve barrel C is rotated, the first terminal a1 fixedly connected to the main barrel a moves in the first linear groove C1 of the curve barrel C along the length direction of the first linear groove C1, and guides the curve barrel C to rotate relative to the main barrel a about the optical axis z, and during the rotation of the curve barrel C, the first linear groove C1 restrains the curve barrel C from being stationary in the length direction of the optical axis z. The rotating curved barrel C drives the second terminal D1 to move in the second strip-shaped groove C2 along the length direction of the second strip-shaped groove C2 through the second strip-shaped groove C2, and since the second strip-shaped groove C2 is not perpendicular to the optical axis z, the second terminal D1 drives the first barrel D to move in the length direction of the optical axis z. Thus, the first lens group D in the first lens barrel D can move in the length direction of the optical axis z (towards the mirror group or away from the mirror group in the length direction of the optical axis z).

The following describes the moving manner of the second lens group E according to fig. 5:

as can be seen from fig. 5, the length direction of the third stripe-shaped groove a3 on the main barrel a is not perpendicular to the optical axis z (i.e. the length direction of the third stripe-shaped groove a3 forms an acute angle with the optical axis z). With such a structure, when the third terminal e3 fixedly connected to the second barrel (not shown in fig. 4) is moved, the third slot a3 restricts the moving direction of the third terminal e3, so that the third terminal e3 moves along the length direction of the third slot a3, and further drives the second barrel to rotate around the optical axis z and move along the length direction of the optical axis z. Thus, the second lens group in the second lens barrel can move in the length direction of the optical axis z (can move towards the mirror group or move away from the mirror group in the length direction of the optical axis z).

As shown in fig. 6, which is an exploded schematic view of the projection lens shown in fig. 2, the third barrel B, the second barrel E, the main barrel a, the curved barrel C, the first barrel D, the base 21 and the mirror group 23 may be assembled in a direction indicated by a dotted line.

In an application environment of the projection lens provided in the embodiment of the present application, when the second lens group is adjusted by 0.1mm along the length direction of the optical axis z, the MTF at each position of the image before adjustment and the MTF at each position after adjustment can be as shown in table 1 below:

TABLE 1

When the first lens group is adjusted by 0.2mm along the length direction of the optical axis z, the MTF at each position of the front image and the MTF at each position after adjustment can be shown in table 2 below:

TABLE 2

The MTF is a Modulation Transfer Function (Modulation Transfer Function), the maximum value is 1, the higher the value is, the higher the resolution of the picture is (the sharper the picture is imaged), and generally, human eyes consider that the picture is slightly blurred when the value is less than 0.35. As can be seen from table 1, adjusting the first lens group and the second lens group in the direction of the optical axis z can significantly adjust the resolution of the MTF image. So can be through adjusting first mirror group and second mirror group in the direction of optical axis z, make the projection lens that this application embodiment provided can be used for the projection picture of various sizes, for example 60 ~ 110 cun, and can make the resolution of picture higher all the time.

To sum up, the projection lens provided by the embodiment of the present application includes a base, and a refractive lens group and a reflective lens group sequentially arranged in the base along a light exit direction, wherein the refractive lens group includes a lens barrel, and a first lens group, a second lens group and a third lens group sequentially arranged in the lens barrel along the light exit direction, wherein the first lens group is connected with the main lens barrel through a curve barrel and can move relative to the main lens barrel when the curve barrel rotates; the second lens group is connected with the main lens cone through the focusing structure and can move relative to the main lens cone under the action of the focusing structure, so that the first lens group and the second lens group can be moved according to various parameters of a picture to be projected, and the projected picture can meet requirements. The problem that the projection lens in the related art is difficult to meet the requirements of various projection parameters is solved. The applicability of the projection lens is improved, and the projection lens can be suitable for various projection parameters.

In the present invention, the terms "first", "second", and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. The term "plurality" means two or more unless expressly limited otherwise.

The invention is not to be considered as limited to the particular embodiments shown and described, but is to be understood that various modifications, equivalents, improvements and the like can be made without departing from the spirit and scope of the invention.

Claims (10)

1. A projection lens is characterized by comprising a base, and a refraction mirror group and a reflection mirror group which are positioned in the base;

the first lens group, the second lens group and the third lens group are sequentially arranged in the lens cone along the direction close to the reflector group;

the lens cone comprises a main lens cone, a third lens cone and a curve cylinder sleeved outside the main lens cone, the first lens group is connected with the main lens cone through the curve cylinder, the main lens cone is fixedly connected with the base, the third lens group is fixedly connected with the third lens cone, and the third lens cone is fixedly connected with the base;

the lens cone comprises a first lens cone and at least one first adjusting mechanism, the first lens group is positioned in the first lens cone, the main lens cone is sleeved outside the first lens cone, the first lens group is movably connected with the main lens cone, the function of adjusting the first lens group along the length direction of an optical axis comprises adjusting the resolution of a picture, and the optical axis is the optical axis of the projection lens;

the lens cone comprises a focusing structure, the second lens group is connected with the main lens cone through the focusing structure, the second lens group is movably connected with the main lens cone, and the function of adjusting the second lens group along the length direction of the optical axis comprises adjusting the resolution of the left and right upper corners of a picture;

the lens cone comprises a second lens cone, the focusing structure comprises at least one second adjusting mechanism, and the main lens cone is sleeved outside the second lens cone;

the third lens group is fixedly connected with the main lens cone;

each first adjusting mechanism comprises a first strip-shaped groove and a second strip-shaped groove, the first strip-shaped groove and the second strip-shaped groove are positioned on the wall of the curve barrel, the length direction of the first strip-shaped groove is perpendicular to the optical axis of the projection lens, and the length direction of the second strip-shaped groove is not perpendicular to the optical axis;

each first adjusting mechanism comprises a first terminal positioned on the cylinder wall of the main lens barrel, the first terminal is fixedly connected with the cylinder wall of the main lens barrel and matched with the first strip-shaped groove, and can move along the length direction of the first strip-shaped groove relative to the curve cylinder when the curve cylinder rotates by taking the axis of the curve cylinder as a shaft;

each first adjusting mechanism comprises a second terminal located on the cylinder wall of the first lens barrel, the second terminal is fixedly connected with the cylinder wall of the first lens barrel, each first adjusting mechanism comprises a strip-shaped through hole located on the cylinder wall of the main lens barrel and parallel to the optical axis in the length direction, the second terminal penetrates through the strip-shaped through hole to be matched with a second strip-shaped groove in the curve cylinder, and the second terminal can move along the length direction of the second strip-shaped groove relative to the curve cylinder when the curve cylinder rotates by taking the axis of the curve cylinder as an axis.

2. The projection lens of claim 1, wherein the axes of the curved cylinder, the main barrel, and the first barrel are parallel to each other.

3. The projection lens according to claim 1, wherein the axis of the second barrel is parallel to the axis of the main barrel;

each second adjusting mechanism comprises a third strip-shaped groove positioned on the cylinder wall of the main lens barrel, and the length direction of the third strip-shaped groove is not perpendicular to the optical axis;

each second adjusting mechanism comprises a third terminal located on the cylinder wall of the second lens barrel, and the third terminal is matched with the third strip-shaped groove and can move in the third strip-shaped groove along the length direction of the third strip-shaped groove.

4. The projection lens of claim 3, wherein the third stripe groove penetrates through the barrel wall of the main barrel, and the third terminal extends from the third stripe groove to the outside of the main barrel.

5. The projection lens of claim 1 wherein the set of mirrors are movably coupled to the base and are capable of moving along the length of the optical axis to adjust the resolution of the projection lens.

6. The projection lens of claim 1, wherein the base has at least two threaded holes, a fixing plate extends from the outside of the main barrel, the fixing plate has at least two through holes, and the fixing plate is fixedly connected to the at least two threaded holes through the at least two through holes and at least two screws.

7. The projection lens of claim 6, wherein the base has at least two position-limiting rods, the fixing plate has at least two position-limiting holes, and when the main barrel is fixed on the base, the at least two position-limiting rods are inserted into the at least two position-limiting holes in a one-to-one correspondence.

8. The projection lens according to claim 1, wherein a first connection plate extends from the outside of the third barrel, a second connection plate extends from the outside of the main barrel, the first connection plate and the second connection plate are fixedly connected by at least four screws, and the at least four screws surround the third barrel.

9. The projection lens of claim 1 wherein the first lens group moves along the length direction of the optical axis of the projection lens under the adjustment of the curve cylinder;

the second lens group moves along the length direction of the optical axis of the projection lens under the adjustment of the focusing structure.

10. A laser projection device, wherein the laser projection device comprises a light source, a light valve, a screen and the projection lens of any one of claims 1 to 9;

the light source is used for providing a laser beam to the light valve;

the light valve is used for modulating the laser beam provided by the light source and then emitting the laser beam to the projection lens;

the projection lens is used for imaging the laser beam provided by the light valve and then emitting the laser beam to a screen.

Images