CN220173115U - Opposite piezoelectric cradle head - Google Patents

Abstract

The utility model belongs to the technical field of optical imaging equipment, and particularly relates to a pair of opposite piezoelectric holders. The utility model provides a pair of vertical piezoelectricity cloud platform, includes shell, base, drive assembly, carrier and built-in circuit, has the cavity between shell and the base, and drive assembly and carrier set up in the cavity, and drive assembly includes: the piezoelectric driving mechanism is arranged on the base, is positioned outside the carrier, is connected with a built-in circuit in the base, and is electrified to drive the carrier to reciprocate along the optical axis direction; and the auxiliary driving mechanism is symmetrically arranged on the base, is positioned outside the carrier and is connected or abutted with the carrier. The utility model adopts the driving mode of the piezoelectric driving mechanism to reciprocate the carrier along the optical axis direction, thereby realizing the zooming operation of the lens, avoiding the problems of arrangement of magnets and magnetic field interference, and being capable of carrying out miniaturization and light-weight arrangement according to the specification of the lens in the carrier.

Description

Opposite piezoelectric cradle head

Technical Field

The utility model belongs to the technical field of optical imaging equipment, and particularly relates to a pair of opposite piezoelectric holders.

Background

With the development of technology, many electronic devices (such as smart phones or digital cameras) have photographing or video recording functions. The use of these electronic devices is becoming more and more popular and is evolving towards a convenient and light-weight design that provides more options for the user.

Some electronic devices with photographing or video recording function are provided with a lens driving device to drive an optical component such as a lens to move so as to achieve an auto focus (auto focus) function. The light can be imaged through the optical assembly onto the photosensitive assembly.

In order to achieve an auto-focusing function, an existing lens driving device generally includes a magnet set, an AF coil, and a carrier for mounting a lens, and the carrier reciprocates along an optical axis direction together with the lens under the action of the AF coil and the magnet set, thereby achieving an auto-focusing operation of the lens.

The AF coil and the magnet set are matched to drive, and the generated magnetic field can interfere other electronic components in the mobile phone. In addition, the magnet group is generally provided with a plurality of magnets, and when the distance between two adjacent magnets is relatively close, the internal magnetic fields of the magnets are mutually interfered, so that unexpected displacement or shaking is generated, and the stability of automatic focusing control is reduced. If the distance between two adjacent magnets is far, the miniaturization development direction of the electronic device is affected.

Disclosure of Invention

The utility model aims at the technical problems and aims at providing a pair of opposite piezoelectric holders.

In order to solve the above-mentioned problem, according to an aspect of the present utility model, there is provided a pair of stereoscopic piezoelectric head including a housing, a base, a driving assembly, a carrier and a built-in circuit, the housing and the base having a hollow cavity therebetween, the driving assembly and the carrier being disposed in the hollow cavity, the driving assembly comprising:

the piezoelectric driving mechanism is arranged on the base, is positioned outside the carrier, is connected with a built-in circuit in the base, and is electrified to drive the carrier to reciprocate along the optical axis direction;

and the auxiliary driving mechanism is symmetrically arranged on the base, is positioned outside the carrier and is connected or abutted with the carrier.

The utility model eliminates the prior mode of driving the carrier by adopting the matching of the AF coil and the magnet set, but adopts the driving mode of the piezoelectric driving mechanism, and realizes the reciprocating motion of the carrier along the optical axis direction after the built-in circuit electrifies the piezoelectric driving mechanism, thereby realizing the zoom operation of the lens. In this driving method, the arrangement of magnets and the problem of magnetic field interference are not required to be considered, and the arrangement of miniaturization and light weight can be performed according to the specification of the lens in the carrier.

In addition, the piezoelectric driving mechanism and the auxiliary driving mechanism matched with the piezoelectric driving mechanism are symmetrically arranged on the base, so that a vertical driving mode is realized, the piezoelectric driving mechanism and the auxiliary driving mechanism can symmetrically clamp the carrier to perform reciprocating motion, and the limiting and guiding effects on the carrier are realized under the matching of the auxiliary driving mechanism, so that the whole automatic focusing process is stable and reliable.

The piezoelectric driving mechanism includes:

the two ends of the reed are fixed with the outer side of the carrier;

the inner side of the movable block is fixed with the middle part of the reed, and the outer side of the movable block is provided with a V-shaped clamping groove;

the piezoelectric mechanism comprises a balancing weight, a deformation block and a friction rod, wherein the balancing weight is arranged on the base, the deformation block is arranged at the top end of the balancing weight, the deformation block is connected with the built-in circuit, the friction rod is arranged at the top end of the deformation block, and the friction rod is contacted with the V-shaped clamping groove;

after the deformation block is electrified, the deformation block generates deformation along the optical axis direction, the friction rod drives the movable block to move along the optical axis direction, the inner side of the movable block is extruded into the movable block mounting groove by the friction rod, under the action of the reed, the reed generates reverse elastic force on the movable block, so that the movable block is extruded on the friction rod, extrusion friction force between the movable block and the friction rod is increased, and when the piezoelectric mechanism moves, the friction rod drives the movable block and the carrier to move along the optical axis direction by the extrusion friction force.

The base is provided with a mounting protrusion, the mounting protrusion is provided with a balancing weight mounting groove, and the balancing weight is mounted in the balancing weight mounting groove.

The outside of carrier is provided with movable block mounting groove, the movable block mounting groove with inside and outside relative setting of movable block.

The auxiliary driving mechanism adopts the same structure as the piezoelectric driving mechanism.

The auxiliary driving mechanism adopts a ball anti-friction mechanism.

The ball antifriction mechanism includes:

the mounting piece is arranged on the base, and a ball connecting piece mounting groove is formed in the inner side of the mounting piece;

the ball connecting piece is arranged in the ball connecting piece mounting groove and is clamped with the ball connecting piece mounting groove;

the baffle plate is arranged at the top end of the mounting piece, is positioned above the ball connecting piece and limits the ball connecting piece, and the bottom end of the baffle plate is provided with a ball avoiding groove;

the first ball mounting groove is formed in the upper end of the ball connecting piece, a first ball limiting protrusion is arranged at the inner end of the first ball mounting groove, a first elastic piece is arranged at the outer end of the first ball mounting groove, the first ball limiting protrusion, the first elastic piece and the ball avoiding groove form a first surrounding space for placing balls together;

the first ball is placed in the first surrounding space, the outer end of the first ball is contacted with the first elastic sheet, and the inner end of the first ball penetrates through the first ball limiting protrusion to be abutted to the outer side wall of the carrier.

The base is provided with a glue groove, and the mounting piece is bonded with the base through the glue groove.

The base upper end is provided with the location arch, the installed part bottom is provided with the constant head tank, the installed part pass through the constant head tank with the location is protruding to cooperate to realize the location.

The inner side of the ball connecting piece mounting groove is provided with a clamping protrusion, the inner end of the ball connecting piece is provided with a clamping groove, and the ball connecting piece is clamped with the clamping protrusion through the clamping groove to realize clamping limit with the ball connecting piece mounting groove.

The inner side of the lower end of the ball connecting piece is provided with a second ball limiting protrusion, and the outer side of the lower end of the ball connecting piece is provided with a second elastic piece;

the ball antifriction mechanism further includes:

the second ball mounting groove is arranged in the mounting piece, and the second ball mounting groove, the second ball limiting protrusion and the second elastic piece jointly form a second surrounding space for placing balls;

the second ball is placed in the second surrounding space and is positioned below the first ball, the outer end of the second ball is contacted with the second elastic sheet, and the inner end of the second ball penetrates through the second ball limiting protrusion to be abutted to the outer side wall of the carrier.

The first elastic piece and the second elastic piece are arranged in an up-down symmetrical mode, and the first elastic piece and the second elastic piece penetrate through the ball connecting piece through a metal reed to form the ball connecting piece.

The first elastic piece, the second elastic piece and the ball connecting piece are all integrally formed by plastic.

The beneficial effects are that: the utility model has at least one or more of the following advantages:

1. the piezoelectric driving mechanism is adopted to drive the carrier to reciprocate along the optical axis direction, so that the zooming operation of the lens is realized, the problems of arrangement of magnets and magnetic field interference are not required to be considered, and the miniaturization and light-weight arrangement can be performed according to the specification of the lens in the carrier.

2. Two piezoelectric driving mechanisms symmetrically arranged at two end angle positions on the base act together, and simultaneously reciprocate the carrier along the optical axis direction from two ends, so that the automatic focusing stability and reliability of the carrier and the lens in the carrier are ensured.

3. The design of the piezoelectric driving mechanism and the ball anti-friction mechanism which are symmetrically arranged on the base is that the ball anti-friction mechanism realizes the limiting and guiding functions on the carrier when the piezoelectric driving mechanism reciprocates along the optical axis direction on the carrier, and the ball anti-friction mechanism does not have piezoelectric materials, so that the cost can be saved.

Drawings

FIG. 1 is a schematic representation of one embodiment of the present utility model;

FIG. 2 is a cross-sectional view of FIG. 1;

FIG. 3 is an exploded view of FIG. 1;

FIG. 4 is a further exploded view of FIG. 3;

FIG. 5 is an exploded view of the piezoelectric driving mechanism of FIG. 3 disposed on a base;

FIG. 6 is an exploded view of the piezoelectric driving mechanism of FIG. 3 coupled to a carrier;

FIG. 7 is an enlarged view of a portion of two piezoelectric actuation mechanisms of FIG. 3;

FIG. 8 is an exploded view of one of the piezoelectric actuation mechanisms of FIG. 3;

FIG. 9 is a partial exploded view of FIG. 8;

FIG. 10 is a schematic diagram of another embodiment of the present utility model;

FIG. 11 is a cross-sectional view of FIG. 10;

FIG. 12 is an exploded view of FIG. 10;

FIG. 13 is a further exploded view of FIG. 12;

FIG. 14 is an exploded view of the piezoelectric drive mechanism, ball anti-friction mechanism of FIG. 12, coupled to a carrier;

FIG. 15 is a perspective view of the piezoelectric driving mechanism and the ball anti-friction mechanism of FIG. 12 disposed on a base;

FIG. 16 is an exploded view of the ball anti-friction mechanism of FIG. 12;

FIG. 17 is a further exploded view of FIG. 16;

FIG. 18 is a partial exploded view of FIG. 16;

FIG. 19 is a diagram showing the relationship among the ball joint, the first spring, the second spring, the first ball and the second ball in FIG. 16;

fig. 20 is a positional relationship diagram of the ball connecting member, the first elastic piece, the second elastic piece, the first ball limiting protrusion and the second ball limiting protrusion in fig. 16.

Detailed Description

The preferred embodiments of the present utility model will be described in detail below with reference to the attached drawings, so that the objects, features and advantages of the present utility model will be more clearly understood. It should be understood that the embodiments shown in the drawings are not intended to limit the scope of the utility model, but rather are merely illustrative of the true spirit of the utility model.

In the following description, for the purposes of explanation of various disclosed embodiments, certain specific details are set forth in order to provide a thorough understanding of the various disclosed embodiments. One skilled in the relevant art will recognize, however, that an embodiment may be practiced without one or more of the specific details. In other instances, well-known devices, structures, and techniques associated with the present utility model may not be shown or described in detail to avoid unnecessarily obscuring the description of the embodiments.

Reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, appearances of the phrases "in one embodiment" or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

In the following description, for the purposes of clarity of presentation of the structure and manner of operation of the present utility model, the description will be made with the aid of directional terms, but such terms as "forward," "rearward," "left," "right," "outward," "inner," "outward," "inward," "upper," "lower," etc. are to be construed as convenience, and are not to be limiting.

Example 1:

referring to fig. 1 to 9, the present embodiment provides a pair of opposite piezoelectric holders, which includes a housing 1, a base 2, a driving assembly, a carrier 5, and a built-in circuit, wherein a hollow cavity is formed between the housing 1 and the base 2, and the housing 1 and the base 2 are preferably connected by buckling to form the hollow cavity. The driving component and the carrier 5 are arranged in the hollow cavity, and the middle parts of the shell 1, the base 2, the driving component and the carrier 5 are provided with lens through holes which are axially communicated along the up-down direction so as to accommodate the lenses.

The driving assembly comprises two piezoelectric driving mechanisms, namely a piezoelectric driving mechanism 3 and a piezoelectric driving mechanism 4, and the piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 adopt the same structure. The piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 are symmetrically arranged at two end angle positions of the base 2. The piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 are both positioned outside the carrier 5 and connected with the carrier 5. The piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 are respectively connected with a built-in circuit in the base 2, and the piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 respectively drive the carrier 5 to reciprocate along the up-down direction after being electrified.

The utility model eliminates the prior mode of driving the carrier 5 by matching the AF coil and the magnet group, but adopts the driving mode of two symmetrically arranged piezoelectric driving mechanisms, and realizes the reciprocating motion of the carrier 5 along the optical axis direction after the built-in circuit electrifies the piezoelectric driving mechanisms, thereby realizing the zoom operation of the lens. In this driving method, the arrangement of magnets and the problem of magnetic field interference are not required to be considered, and the arrangement of miniaturization and light weight can be performed according to the specifications of the lens in the carrier 5.

In addition, the utility model realizes a vertical driving mode by the two piezoelectric driving mechanisms symmetrically arranged on the base 2, and the two piezoelectric driving mechanisms can not only symmetrically clamp the carrier 5 to reciprocate, but also realize the limiting and guiding functions on the carrier 5, so that the whole automatic focusing process is stable and reliable.

Alternatively, referring to fig. 7 to 9, the piezoelectric driving mechanism 3 and the piezoelectric driving mechanism 4 adopt the same structure, and the piezoelectric driving mechanism 3 includes a reed 32, a movable block 33, and a piezoelectric mechanism including a weight 34, a deforming block 35, and a friction rod 36, as an example of the piezoelectric driving mechanism 3.

In this example, a piezoelectric mounting portion 31 is provided on the outer side of the carrier 5, and the carrier 5 is connected to both ends of the reed 32 of the piezoelectric driving mechanism 3 through the piezoelectric mounting portion 31, and the piezoelectric mounting portion 31 and the carrier 5 are designed to be separated. In some embodiments, the piezoelectric mounting portion 31 is integrally designed with the carrier 5, i.e., two ends of the reed 32 of the piezoelectric driving mechanism 3 are directly connected to the outside of the carrier 5.

Both ends of the reed 32 are fixed to the outside of the piezoelectric mount 31. The inner side of the movable block 33 is fixed with the middle part of the reed 32, and the outer side of the movable block 33 is provided with a V-shaped clamping groove 331.

The balancing weight 34 is arranged on the base 2, a deformation block 35 is arranged at the top end of the balancing weight 34, the deformation block 35 is connected with a built-in circuit, a friction rod 36 is arranged at the top end of the deformation block 35, and the friction rod 36 is contacted with the V-shaped clamping groove 331. After the deformation block 35 is electrified, the deformation block 35 generates deformation along the optical axis direction, the friction rod 36 drives the movable block 33 to move along the optical axis direction, the inner side of the movable block 33 is extruded into the movable block mounting groove 311 by the friction rod 36, under the action of the reed 32, the reed 32 generates reverse elastic force on the movable block 33, so that the movable block 33 is extruded on the friction rod 36, the extrusion friction force between the movable block 33 and the friction rod 36 is increased, and when the piezoelectric mechanism moves, the friction rod 36 drives the movable block 33, the piezoelectric mounting part 31 and the carrier 5 to move along the optical axis direction through the extrusion friction force.

Optionally, the side of the friction bar 36 contacting the V-shaped clamping groove 331 is arcuate.

Optionally, a pressing groove 321 is formed in the middle of the reed 32, and the inner side of the movable block 33 is fixed to the reed 32 at two sides of the pressing groove 321. When the friction rod 36 drives the movable block 33 to move along the optical axis direction, after the inner side of the movable block 33 is extruded by the friction rod 36, the middle part of the inner side of the movable block 33 passes through the extrusion groove 321 to be extruded into the movable block mounting groove 311, and the movable block 33 is extruded on the friction rod 36 by the reverse elastic force generated by the reeds 32 at the two sides of the extrusion groove 321.

Alternatively, the upper and lower sides of the extrusion groove 321 are respectively provided with a straight groove 322 which is internally and externally communicated along the length direction of the reed 32, and the straight groove 322 is communicated with the extrusion groove 321, so that two elastic sheets 323 are formed on the two sides of the extrusion groove 321.

Optionally, at least one reed groove 324 for increasing the flexibility of the reed 32 and communicating the inside and the outside is formed in each of the two elastic sheets 323. As shown in fig. 9, two reed grooves 324 are provided in the up-down direction on the elastic sheet 323, respectively.

Optionally, two mounting protrusions 21 are provided on the base 2, and the two mounting protrusions 21 are symmetrically provided at two end angular positions of the base 2. Each mounting protrusion 21 is provided with a balancing weight mounting groove 22, and the balancing weights 34 of the piezoelectric driving mechanism 3 and the balancing weights of the piezoelectric driving mechanism 4 are respectively arranged in the two symmetrically arranged balancing weight mounting grooves 22.

Alternatively, the piezoelectric mounting portion 31 has a sheet structure, the inner side of the piezoelectric mounting portion 31 is connected with the carrier 5, the outer side of the piezoelectric mounting portion 31 is provided with a movable block mounting groove 311, and the movable block mounting groove 311 is disposed opposite to the inner side and the outer side of the movable block 33.

Optionally, a carrier mounting groove 312 is provided on the inner side of the piezoelectric mounting portion 31, and the carrier mounting groove 312 has a flared structure, and the carrier mounting groove 312 is adapted to the outer diameter of the carrier 5, so as to increase the contact surface between the piezoelectric mounting portion 31 and the carrier 5. For example, as shown in fig. 3 and 6, when the carrier 5 has an octagonal-structured outer shape, one of the sides is restrained as a connecting side in the carrier mounting groove 312, and the flare surfaces of the flare-like structures are fitted to the adjacent two sides of the connecting side.

Alternatively, in order to enhance the stability of the connection structure, the piezoelectric mounting portion 31 is connected to the carrier 5 by adhesion.

Alternatively, the piezoelectric mounting portion 31 is integrally formed with the carrier 5, and the piezoelectric mounting portion 31 is a part of the carrier 5, so that it can be regarded that the movable block mounting groove 311 is directly provided on the outer side of the carrier 5, and the movable block mounting groove 311 is provided opposite to the inner side and the outer side of the movable block 33.

Example 2:

referring to fig. 10 to 20, the present embodiment provides a pair of opposing piezoelectric holders, in which the piezoelectric driving mechanism 4 is replaced with a ball anti-friction mechanism 6, and the connection relationship between the ball anti-friction mechanism 6 and the base 2 and the connection relationship between the piezoelectric driving mechanism 4 and the base 2 are different from those of embodiment 1. The rest of the structure of this embodiment is the same as that of embodiment 1, and will not be described here again.

Referring to fig. 16 to 20, the ball anti-friction mechanism 6 of the present embodiment includes a mounting member 61, a ball connecting member 62, a shutter 63, a first ball mounting groove 641, a first ball restricting projection 642, a first elastic piece 643, and a first ball 65.

The mounting member 61 is provided on the base 2, and the inner side of the mounting member 61 is provided with a ball-joint-member mounting groove 611. The ball connecting piece 62 is disposed in the ball connecting piece mounting groove 611 and is clamped with the ball connecting piece mounting groove 611, so that the ball connecting piece 62 cannot be separated from the ball connecting piece mounting groove 611 after being placed in the ball connecting piece mounting groove 611. The baffle 63 is arranged at the top end of the mounting piece 61, the baffle 63 is arranged above the ball connecting piece 62 and limits the ball connecting piece 62, and the bottom end of the baffle 63 is provided with a ball avoiding groove 631. The first ball mounting groove 641 is formed in the upper end of the ball connecting piece 62, a first ball limiting protrusion 642 is arranged at the inner end of the first ball mounting groove 641, a first elastic sheet 643 is arranged at the outer end of the first ball mounting groove 641, and the first ball mounting groove 641, the first ball limiting protrusion 642, the first elastic sheet 643 and the ball avoiding groove 631 form a first surrounding space for placing balls. The first ball 65 is disposed in the first surrounding space, the outer end of the first ball 65 contacts with the first elastic piece 643, the first elastic piece 643 gives a certain elastic force to the first ball 65, and under the elastic force, the inner end of the first ball 65 passes through the first ball limiting protrusion 642 and tightly abuts against the outer side wall of the carrier 5. When the carrier 5 moves up and down, the first ball 65 rotates in the first surrounding space to reduce the friction force when the carrier 5 moves up and down, and meanwhile, the first ball can limit the carrier 5 to avoid the deviation phenomenon in the up and down movement process.

In this embodiment, a piezoelectric driving mechanism 3 and a ball anti-friction mechanism 6 are provided at both end angular positions of the base 2, respectively, and the piezoelectric driving mechanism 3 has the same structure as that of embodiment 1. The ball antifriction mechanism 6 does not have a piezoelectric material and can save cost.

Optionally, the baffle 63 may be adhesively attached to the top of the mounting member 61 to limit the position of the ball connector 62 above it.

Optionally, the base 2 is provided with a glue groove 23, and the mounting piece 61 is adhered to the base 2 by glue filled in the glue groove 23.

Optionally, the upper end of the base 2 is provided with a positioning protrusion 24, the bottom end of the mounting piece 61 is provided with a positioning groove 612, and the mounting piece 61 is matched with the positioning protrusion 24 through the positioning groove 612 to realize positioning. As shown in fig. 12, two positioning protrusions 24 are disposed at the upper end of the base 2 and are respectively distributed on two adjacent sides. The mounting member 61 has a triangular prism-like structure, and two positioning grooves 612 are formed on two sides of the bottom end of the mounting member. When the mount 61 is placed on the base 2, the two positioning grooves 612 are supported on the two positioning projections 24, respectively.

Alternatively, the glue groove 23 is located at an end angle position of the base 2, and two positioning protrusions 24 are located at two sides of the glue groove 23 respectively.

Alternatively, referring to fig. 13 and 14, when two mounting protrusions 21 are provided on the base 2, the adhesive grooves 23 are symmetrically provided at two diagonal positions on the base 2 with respect to the mounting protrusions 21.

Alternatively, referring to fig. 16, the inner side of the ball connector mounting groove 611 is provided with a clamping protrusion 613, the inner end of the ball connector 62 is provided with a clamping groove 621, and the ball connector 62 is clamped with the clamping protrusion 613 through the clamping groove 621 to achieve clamping limitation with the ball connector mounting groove 611.

Optionally, the ball anti-friction mechanism 6 further includes a second ball mounting groove 661, a second ball limiting protrusion 662, a second elastic piece 663, and a second ball 67.

The inner side of the lower end of the ball connecting piece 62 is provided with a second ball limiting protrusion 662, and the outer side of the lower end of the ball connecting piece 62 is provided with a second elastic piece 663. The second ball mounting groove 661 is provided in the mounting piece 61, and the second ball mounting groove 661, the second ball limiting projection 662 and the second elastic piece 663 together form a second surrounding space for placing the balls. The second ball 67 is placed in the second surrounding space, the second ball 67 is located below the first ball 65, the outer end of the second ball 67 is in contact with the second elastic sheet 663, the second elastic sheet 663 gives a certain elastic force to the second ball 67, and under the elastic force, the inner end of the second ball 67 passes through the second ball limiting protrusion 662 and is tightly abutted to the outer side wall of the carrier 5. When the carrier 5 moves up and down, the second ball 67 rotates in the second surrounding space to reduce the friction force of the carrier 5 during up and down movement, and meanwhile, the second ball can limit the carrier 5 to avoid deviation in the up and down movement process. So that the carrier 5 is restrained and friction is reduced by the combination of the first balls 65 and the second balls 67.

Alternatively, the first elastic piece 643 and the second elastic piece 663 are vertically symmetrically arranged, and the first elastic piece 643 and the second elastic piece 663 are formed by penetrating the ball connecting piece 62 through a metal reed.

Alternatively, the first elastic piece 643 and the second elastic piece 663 may also be reeds with plastic structures, and the ball connecting piece 62 is also with plastic structures, so that the first elastic piece 643, the second elastic piece 663 and the ball connecting piece 62 are all integrally formed by plastic.

While the preferred embodiments of the present utility model have been described in detail, it will be appreciated that those skilled in the art, upon reading the above teachings, may make various changes and modifications to the utility model. Such equivalents are also intended to fall within the scope of the utility model as defined by the following claims.

Claims (10)

1. The utility model provides a pair of vertical piezoelectric cloud platform, includes shell, base, drive assembly, carrier and built-in circuit, have the cavity between shell and the base, drive assembly with the carrier sets up in the cavity, its characterized in that, drive assembly includes:

the piezoelectric driving mechanism is arranged on the base, is positioned outside the carrier, is connected with a built-in circuit in the base, and is electrified to drive the carrier to reciprocate along the optical axis direction;

and the auxiliary driving mechanism is symmetrically arranged on the base, is positioned outside the carrier and is connected or abutted with the carrier.

2. The opposed piezoelectric holder of claim 1, wherein the piezoelectric driving mechanism comprises:

the two ends of the reed are fixed with the outer side of the carrier;

the inner side of the movable block is fixed with the middle part of the reed, and the outer side of the movable block is provided with a V-shaped clamping groove;

the piezoelectric mechanism comprises a balancing weight, a deformation block and a friction rod, wherein the balancing weight is arranged on the base, the deformation block is arranged at the top end of the balancing weight, the deformation block is connected with the built-in circuit, the friction rod is arranged at the top end of the deformation block, and the friction rod is in contact with the V-shaped clamping groove.

3. The counter-type piezoelectric tripod head of claim 2, wherein a mounting protrusion is provided on said base, a weight block mounting groove is provided on said mounting protrusion, and said weight block is mounted in said weight block mounting groove.

4. The opposed piezoelectric holder of claim 2, wherein the carrier is provided with a movable block mounting groove on an outer side thereof, the movable block mounting groove being disposed opposite to an inner side and an outer side of the movable block.

5. The opposed piezoelectric pan-tilt of any of claims 1 to 4, wherein the auxiliary drive mechanism is of the same construction as the piezoelectric drive mechanism.

6. The opposing piezoelectric holder of any one of claims 1 to 4, wherein the auxiliary drive mechanism employs a ball anti-friction mechanism comprising:

the mounting piece is arranged on the base, and a ball connecting piece mounting groove is formed in the inner side of the mounting piece;

the ball connecting piece is arranged in the ball connecting piece mounting groove and is clamped with the ball connecting piece mounting groove;

the baffle plate is arranged at the top end of the mounting piece, is positioned above the ball connecting piece and limits the ball connecting piece, and the bottom end of the baffle plate is provided with a ball avoiding groove;

the first ball mounting groove is formed in the upper end of the ball connecting piece, a first ball limiting protrusion is arranged at the inner end of the first ball mounting groove, a first elastic piece is arranged at the outer end of the first ball mounting groove, the first ball limiting protrusion, the first elastic piece and the ball avoiding groove form a first surrounding space for placing balls together;

the first ball is placed in the first surrounding space, the outer end of the first ball is contacted with the first elastic sheet, and the inner end of the first ball penetrates through the first ball limiting protrusion to be abutted to the outer side wall of the carrier.

7. The opposite type piezoelectric tripod head of claim 6, wherein said base is provided with a glue groove, and said mounting member is adhered to the base through the glue groove;

the base upper end is provided with the location arch, the installed part bottom is provided with the constant head tank, the installed part pass through the constant head tank with the location is protruding to cooperate to realize the location.

8. The opposite type piezoelectric holder according to claim 6, wherein a clamping protrusion is provided on an inner side of the ball connecting piece mounting groove, a clamping groove is provided on an inner end of the ball connecting piece, and the ball connecting piece is clamped with the clamping protrusion through the clamping groove to achieve clamping limitation with the ball connecting piece mounting groove.

9. The opposite type piezoelectric tripod head of claim 6, wherein a second ball limiting protrusion is arranged on the inner side of the lower end of said ball connecting piece, and a second elastic piece is arranged on the outer side of the lower end of said ball connecting piece;

the ball antifriction mechanism further includes:

the second ball mounting groove is arranged in the mounting piece, and the second ball mounting groove, the second ball limiting protrusion and the second elastic piece jointly form a second surrounding space for placing balls;

the second ball is placed in the second surrounding space and is positioned below the first ball, the outer end of the second ball is contacted with the second elastic sheet, and the inner end of the second ball penetrates through the second ball limiting protrusion to be abutted to the outer side wall of the carrier.

10. The opposite type piezoelectric tripod head of claim 9, wherein said first elastic sheet and said second elastic sheet are vertically symmetrically arranged, and said first elastic sheet and said second elastic sheet are formed by penetrating a metal reed through said ball connecting member;

or alternatively, the first and second heat exchangers may be,

the first elastic piece, the second elastic piece and the ball connecting piece are all integrally formed by plastic.