CN218920522U - Remote control angle adjusting structure for camera lens - Google Patents

Abstract

The utility model provides a remote control angle adjusting structure of a camera lens, which comprises a control base and an adjusting mechanism. This camera lens remote control angle adjustment structure charges for it through the mouth that charges earlier, then put into fixed sleeve with the camera lens, it is aerifyd for its inside inflatable airbag through the inflator, fixed with the camera lens, starting drive, the battery is supplied power for its internal component, observe the behavior of device through the pilot lamp, the normal clear instruction device normal operating of pilot lamp, remove the end and take place wireless signal for wireless signal receiver, wireless signal receiver transmits control chip after with signal processing, control chip begins to adjust height and angle, first lifter block and second lifter block are flexible to be gone on to the height, the motor drives the rotation axis and carries out angle adjustment to the rotation post, the inside of rotation post is provided with the steering wheel, it rotates to drive the axis of rotation, carry out angle adjustment to the spliced pole, thereby reach the purpose of constructing a long-range angle adjustment.

Description

Remote control angle adjusting structure for camera lens

Technical Field

The utility model relates to the technical field of remote control, in particular to a remote control angle adjusting structure of a camera lens.

Background

In actual use, an aircraft often encounters climatic environments such as high temperature, low temperature, damp heat, sunlight, rainfall, fog reduction, freezing rain, strong wind, snow reduction and the like, and sometimes the complex extreme climatic environment causes the problem of environmental adaptability of the aircraft. For example, the B-1B aircraft in the United states loses the flight capacity in cold weather, and the V-22 fighter ground anti-collision and warning system has problems in an icing environment, so that the fighter crashes many times, and the like. The complete machine climate environment test is a ground verification project performed by an aircraft under extreme climate conditions. The aim of the complete machine climate environment test is to find the defects of the airplane and the ground assurance equipment in the aspect of climate environment adaptability, and to verify the capability of the airplane and the ground assurance equipment to complete the expected tasks according to the technical instruction program under the extreme climate condition. Therefore, there is a particular need for a camera lens remote control angle adjustment structure.

However, in the existing camera lens control angle adjusting structure, in the use process, the general camera lens control angle adjusting structure cannot realize remote control, needs to be controlled by manpower, and sometimes the angle adjustment is limited according to different structures.

Disclosure of Invention

The utility model aims to provide a remote control angle adjusting structure of a camera lens, which solves the problems that in the prior art, the conventional camera lens control angle adjusting structure cannot realize remote control, needs to be controlled by manpower, and sometimes the angle adjustment is limited according to different structures.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a camera lens remote control angle adjustment structure, includes control base and adjustment mechanism, and adjustment mechanism includes battery, control chip, wireless signal receiver, first elevating block, second elevating block, connecting block, column spinner, rotation axis, first knob, motor, supporting shoe, spliced pole, axis of rotation, second knob, fixed sleeve, inflator and inflatable balloon, one side of control base is provided with the fixed block, the inside of fixed block is run through and is provided with the screw, control base's surface is provided with the mouth that charges, one side of the mouth that charges is provided with the pilot lamp, control base's inside is provided with adjustment mechanism.

Preferably, the fixed block is welded with the control base, and the screw is in threaded connection with the fixed block.

Preferably, the adjustment mechanism includes battery, control chip, wireless signal receiver, first elevating block, second elevating block, connecting block, column spinner, rotation axis, first knob, motor, supporting shoe, spliced pole, axis of rotation, second knob, fixed sleeve, inflator and inflatable bladder, the inside of control base is provided with the battery, one side of battery is provided with control chip, one side of control chip is provided with wireless signal receiver, the top of control base is provided with first elevating block, the top of first elevating block is provided with the second elevating block, the top of second elevating block is provided with the connecting block, the inboard of connecting block is provided with the column spinner, the inside of column spinner is run through and is provided with the rotation axis, the one end of rotation axis is provided with first knob, the one end of first knob is provided with the motor, the bottom of motor is provided with the supporting shoe, the one end of column spinner is provided with the spliced pole, the inside of spliced pole is run through and is provided with the axis of rotation, one end of rotation axis is provided with the wireless signal receiver, the one end of spliced pole is provided with the second elevating block, the one end of spliced pole is provided with fixed sleeve, the inside of fixed sleeve is provided with the knob, the inflatable bladder.

Preferably, the first lifting block and the control base are welded, and a telescopic structure is formed between the first lifting block and the second lifting block.

Preferably, the connecting block forms a rotating structure between the rotating shaft and the rotating column, and the inner diameter of the connecting block and the rotating column are matched with the outer diameter of the rotating shaft.

Preferably, the rotating column forms a rotating structure through the rotating shaft and the connecting column, and the inner diameter of the rotating column is matched with the outer diameter of the rotating shaft.

Preferably, the fixing sleeve is connected with the inflatable air bag through a clamping groove, and the fixing sleeve is tightly attached to the inflatable air bag.

Compared with the prior art, the utility model has the beneficial effects that: this camera lens remote control angle adjustment structure, through the battery, a control chip, the wireless signal receiver, first elevating block, the second elevating block, the connecting block, the column spinner, the rotation axis, first knob, a motor, the supporting shoe, the spliced pole, the axis of rotation, the second knob, fixed sleeve, the setting of inflator and inflatable balloon, when using, charge for it through the mouth that charges earlier, then put into fixed sleeve with the camera lens, it is fixed to inflate for its inside inflatable balloon through the inflator, starting drive, the battery supplies power for its internal component, observe the behavior of device through the pilot lamp, the pilot lamp is always bright to explain device normal operating, the mobile terminal takes place wireless signal for the wireless signal receiver, wireless signal receiver transmits control chip after with signal processing, control chip begins to adjust height and angle, first elevating block and second elevating block are flexible to highly going on, the motor drives the rotatory column spinner of rotation axis, the inside of column spinner is provided with the steering wheel, drive rotates the axis of rotation, carry out angle adjustment to the spliced pole, thereby reach the purpose of constructing a long-range angle adjustment.

Drawings

FIG. 1 is a schematic view of the overall left-hand perspective structure of the present utility model;

FIG. 2 is a schematic diagram of the overall right-view perspective of the present utility model;

FIG. 3 is a schematic rear perspective view of the present utility model;

FIG. 4 is a schematic cross-sectional view of a control mount of the present utility model;

FIG. 5 is a schematic view of the structure of the inflatable bladder of the present utility model;

FIG. 6 is a schematic view of an inflator according to the present utility model.

In the figure: 1. a control base; 2. a fixed block; 3. a screw; 4. a charging port; 5. an indicator light; 6. an adjusting mechanism; 601. a battery; 602. a control chip; 603. a wireless signal receiver; 604. a first lifting block, 605, a second lifting block; 606. a connecting block; 607. a spin column; 608. a rotation shaft; 609. a first knob; 610. a motor; 611. a support block; 612. a connecting column; 613. a rotating shaft; 614. a second knob; 615. a fixed sleeve; 616. an inflator; 617. and (5) inflating the air bag.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

1-6, the utility model comprises a control base 1 and an adjusting mechanism 6, wherein the adjusting mechanism 6 comprises a battery 601, a control chip 602, a wireless signal receiver 603, a first lifting block 604, a second lifting block 605, a connecting block 606, a rotating column 607, a rotating shaft 608, a first knob 609, a motor 610, a supporting block 611, a connecting column 612, a rotating shaft 613, a second knob 614, a fixed sleeve 615, an inflator 616 and an inflating airbag 617, one side of the control base 1 is provided with a fixed block 2, a screw 3 penetrates through the inside of the fixed block 2, the surface of the control base 1 is provided with a charging port 4, one side of the charging port 4 is provided with an indicator lamp 5, and the inside of the control base 1 is provided with the adjusting mechanism 6.

In the second embodiment, the fixed block 2 is welded with the control base 1, and the screw 3 is in threaded connection with the fixed block 2, so that the device can be conveniently fixed and detached.

In the third embodiment, the adjusting mechanism 6 includes a battery 601, a control chip 602, a wireless signal receiver 603, a first elevating block 604, a second elevating block 605, a connection block 606, a rotation column 607, a rotation shaft 608, a first knob 609, a motor 610, a support block 611, a connection column 612, a rotation shaft 613, a second knob 614, a fixing sleeve 615, an inflator 616 and an inflatable balloon 617, the battery 601 is disposed in the control base 1, the control chip 602 is disposed on one side of the battery 601, the wireless signal receiver 603 is disposed on one side of the control chip 602, the first elevating block 604 is disposed on the top of the control base 1, the second elevating block 605 is disposed on the top of the first elevating block 604, the connection block 606 is disposed on the top of the second elevating block 605, the rotation column 607 is disposed on the inner side of the connection block 606, the rotation shaft 608 is disposed in the rotation column 607, a first knob 609 is arranged at one end of the rotating shaft 608, a motor 610 is arranged at one end of the first knob 609, a supporting block 611 is arranged at the bottom end of the motor 610, a connecting column 612 is arranged at one end of the rotating column 607, a rotating shaft 613 penetrates through the inside of the connecting column 612, a second knob 614 is arranged at one end of the rotating shaft 613, a fixing sleeve 615 is arranged at one end of the connecting column 612, an inflator 616 is arranged inside the fixing sleeve 615, an inflating airbag 617 is arranged inside the fixing sleeve 615, firstly, the charging port 4 charges the fixing sleeve 615, then a lens is placed in the fixing sleeve 615, the inflating airbag 617 in the fixing sleeve 616 inflates the lens, the lens is fixed, a starting device is started, a battery 601 supplies power for internal elements of the fixing sleeve, the running condition of the device is observed through an indicator lamp 5, the indicator lamp 5 always lights the normal running, the moving end generates a wireless signal for a wireless signal receiver 603, the wireless signal receiver 603 transmits the processed signals to the control chip 602, the control chip 602 starts to adjust the height and the angle, the first lifting block 604 and the second lifting block 605 stretch out and draw back to the height, the motor 610 drives the rotating shaft 608 to rotate to perform angle adjustment on the rotating column 607, a steering engine is arranged in the rotating column 607 to drive the rotating shaft 613 to rotate, and the connecting column 612 is subjected to angle adjustment.

In the fourth embodiment, the first lifting block 604 is welded to the control base 1, and the first lifting block 604 and the second lifting block 605 form a telescopic structure, so that a suitable height can be adjusted according to different requirements.

In the fifth embodiment, the connection block 606 forms a rotation structure between the rotation shaft 608 and the rotation column 607, and the inner diameters of the connection block 606 and the rotation column 607 are matched with the outer diameter of the rotation shaft 608, so that different angles can be adjusted.

In the sixth embodiment, the rotation column 607 forms a rotation structure between the rotation shaft 613 and the connection column 612, the inner diameters of the rotation column 607 and the connection column 612 are matched with the outer diameter of the rotation shaft 613, and the accuracy of the angle is improved by twice angle adjustment.

In the seventh embodiment, the fixing sleeve 615 is connected with the inflatable balloon 617 through a clamping groove, and the fixing sleeve 615 is tightly attached to the inflatable balloon 617, so that the fixing can be more conveniently performed.

Working principle: for a camera lens remote control angle adjusting structure, when the camera lens remote control angle adjusting structure is used, the camera lens remote control angle adjusting structure is fixed through the cooperation between the fixed block 2 and the screw 3 in the first step, the camera lens is charged through the charging port 4 in the second step, then the camera lens is placed into the fixed sleeve 615, the inflatable air bag 617 inside the camera lens is inflated through the inflator 616, the camera lens is fixed, the device is started, the battery 601 supplies power for internal elements of the camera lens remote control angle adjusting structure, the running condition of the device is observed through the indicator lamp 5, the indicator lamp 5 normally lights the normal running of the device, the mobile end sends wireless signals to the wireless signal receiver 603, the wireless signal receiver 603 transmits the processed signals to the control chip 602, the control chip 602 starts to adjust the height and the angle, the first lifting block 604 and the second lifting block 605 stretch out and draw back to the height, the motor 610 drives the rotary shaft 608 to rotate to adjust the angle, the steering engine is arranged inside the rotary shaft 607 to drive the rotary shaft 613 to rotate to adjust the angle of the connecting column 612, and the use process of the camera lens remote control angle adjusting structure is completed.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a camera lens remote control angle adjustment structure, including control base (1) and adjustment mechanism (6), adjustment mechanism (6) include battery (601), control chip (602), wireless signal receiver (603), first elevating block (604), second elevating block (605), connecting block (606), column (607), rotation axis (608), first knob (609), motor (610), supporting shoe (611), spliced pole (612), axis of rotation (613), second knob (614), fixed sleeve (615), inflator (616) and inflatable bag (617), its characterized in that: one side of control base (1) is provided with fixed block (2), the inside of fixed block (2) is run through and is had screw (3), the surface of control base (1) is provided with charge mouth (4), one side of charge mouth (4) is provided with pilot lamp (5), the inside of control base (1) is provided with adjustment mechanism (6).

2. The remote control angle adjusting structure of the camera lens according to claim 1, wherein welding is adopted between the fixed block (2) and the control base (1), and the screw (3) is in threaded connection with the fixed block (2).

3. The remote control angle adjusting structure for camera lens according to claim 1, wherein the adjusting mechanism (6) comprises a battery (601), a control chip (602), a wireless signal receiver (603), a first lifting block (604), a second lifting block (605), a connecting block (606), a rotary column (607), a rotary shaft (608), a first knob (609), a motor (610), a supporting block (611), a connecting column (612), a rotary shaft (613), a second knob (614), a fixing sleeve (615), an inflator (616) and an inflatable airbag (617), the inside of the control base (1) is provided with the battery (601), one side of the battery (601) is provided with the control chip (602), one side of the control chip (602) is provided with the wireless signal receiver (603), the top end of the control base (1) is provided with the first lifting block (604), the top end of the first lifting block (604) is provided with the second lifting block (605), the top end of the second lifting block (605) is provided with the connecting column (606), the inside (607) is provided with the rotary column (608), one end of the rotary column (608) is provided with the rotary shaft (608), one end of first knob (609) is provided with motor (610), the bottom of motor (610) is provided with supporting shoe (611), the one end of column (607) is provided with spliced pole (612), the inside of spliced pole (612) is run through and is had axis of rotation (613), the one end of axis of rotation (613) is provided with second knob (614), the one end of spliced pole (612) is provided with fixed sleeve (615), the inside of fixed sleeve (615) is provided with inflator (616), the inboard of fixed sleeve (615) is provided with inflatable bag (617).

4. A remote control angle adjusting structure for a camera lens according to claim 3, wherein the first lifting block (604) is welded to the control base (1), and the first lifting block (604) and the second lifting block (605) form a telescopic structure.

5. A camera lens remote control angle adjusting structure according to claim 3, wherein the connecting block (606) forms a rotating structure between the rotating shaft (608) and the rotating column (607), and the inner diameters of the connecting block (606) and the rotating column (607) are matched with the outer diameter of the rotating shaft (608).

6. A camera lens remote control angle adjusting structure according to claim 3, wherein the rotary column (607) forms a rotary structure with the connection column (612) through the rotation shaft (613), and the inner diameters of the rotary column (607) and the connection column (612) are matched with the outer diameter of the rotation shaft (613).

7. A camera lens remote control angle adjusting structure according to claim 3, wherein the fixing sleeve (615) is connected with the inflatable balloon (617) through a clamping groove, and the fixing sleeve (615) is tightly attached to the inflatable balloon (617).

Images