JP6795232B1 - LED lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an LED lighting device in which an LED lamp installed in a high place can be easily replaced. An LED lighting device has an LED light bar 1, a mounting column 2, a fixing mechanism 4, a synchronization belt 5, and a drive handle, and the drive handle moves a fixing mechanism 4 that supports the LED light bar 1 up and down through a synchronization wheel. The LED light bar 1 is replaced by moving it. When the fixing mechanism 4 and the LED light bar 1 are in the highest position, the two first fixing blocks are fitted into the two first fixing holes, so that the two first fixing holes stably support the moving block and at the same time. When the fixing mechanism moves downward, the downward traction force is not transmitted to the moving block through the fixing pulley, so the frictional force between the two first fixing blocks and the two first fixing holes does not increase, so two The first fixing block smoothly disengages from the first fixing hole, and the fixing mechanism 4 smoothly moves downward. [Selection diagram] Fig. 3

Description

The present invention relates to a lighting device using LEDs.

Lighting equipment is required to have a high energy-saving effect.
Therefore, LED lighting devices have high value and have been used in a wide range of fields.
In recent years, LED lighting devices have become able to adjust color and brightness by installing a smart control circuit in a power source and performing two circuit outputs of both positive and negative poles.
As a result, various LED lighting devices are installed in parks and amusement parks to illuminate brightly even at night.
In this case, the LED lighting device is installed in a high place in consideration of safety and practicality in order to expand the lighting range and prevent electric shock.
However, when the light bulb is broken or has reached the end of its life, it must be replaced, but it is inconvenient to replace the light bulb of a lighting device installed in a high place.

Therefore, Patent Document 1 discloses a lighting fixture in which an LED lamp can be easily removed or replaced.
The invention of Patent Document 1 is a combination of a removable LED lamp, a removable lamp, a lamp socket and an aluminum substrate so that a damaged part can be easily replaced or the LED lamp can be easily removed. By designing the plate with the aluminum plate in close contact with the heat sink, the LED lamp can dissipate a large amount of heat generated during operation, extend its life and reduce the risk of damage. Is.

CN109185720A Gazette (Application No. CN201811155264.9)

However, the invention of Patent Document 1 only extends the life of the light bulb by using a removable LED lamp and designing it to easily dissipate heat, and the workability associated with the replacement of the LED lamp is taken into consideration. Not.
Therefore, an object of the present invention is to provide a new LED lighting device in order to solve the above problems.

In order to solve the above-mentioned problems in the prior art, the LED lighting device of the present invention takes the following technical solutions.

In the description of the present invention, terms such as "inside", "down", and "up" that indicate the orientation and the positional relationship are based on the orientation shown in the drawing, the orientation often placed during work, and the positional relationship. ..
Also, terms such as "first" and "second" are used only to distinguish the explanations and do not mean to indicate or imply relative importance.

The LED lighting device includes an LED light bar, a mounting column, a fixing mechanism, a synchronization belt, a drive handle, a first synchronization wheel, a first rotation shaft, a second synchronization wheel, and a second rotation shaft.
The mounting column is hollow and has two first fixing holes symmetrically on the inner surface.
When the moving block is in the highest position, the moving block is fixed (supported) in a state where it does not fall by fitting the first fixing block attached to the moving block into the first fixing hole.
In this fixed state, the two first fixing blocks are fitted in the gaps of the corresponding first fixing holes, and the two first fixing holes can stably support the moving block. it can.

A stop block is attached to the side surface of the upper part of the mounting column where the first fixing hole is not opened, and the stop block has a second fixing hole.
In the second fixing hole, when the synchronous belt starts pulling the wire downward, the wire also exerts a downward force on the moving block.
At that time, since the moving block is fixed at the highest position by the combination of the two first fixing blocks and the two first fixing holes, when pulled by the wire, the downward force received by the moving block becomes stronger.

Further, the frictional force between the two first fixing blocks and the first fixing hole becomes stronger, and the resistance force against the downward force received from the first fixing hole of the first fixing block also becomes stronger.
The telescopic shell also increases resistance to the traction of the wire.
In this state, the moving block does not move downward due to the combination of the two first fixing blocks and the two first fixing holes.

However, since the wire goes through the fixed pulley and the fixed pulley is attached to the moving shell, the wire transmits traction to the moving shell through the fixed pulley.
As a result, the moving shell moves downward, and the second fixed block moves downward accordingly.
During the movement, when the lower slope of the second fixing block hits the second fixing hole, the second fixing hole gives an upward bearing capacity to the second fixing block.

Since the inclination angle of the lower slope of the second fixing block with respect to the horizontal direction is small, the second fixing block does not easily return to the moving shell side from the second fixing hole.
Therefore, the second fixing hole provides an upward bearing capacity to the moving shell via the second fixing block.
Since its bearing capacity offsets most of the downward pulling force of the wire, the downward pulling force that the wire has transmitted between the first fixing block and the first fixing hole is reduced, and the resistance of the telescopic shell to the pulling force of the wire. Also becomes smaller.
In this state, when the wire is pulled, the wire moves the telescopic shell.

A shaft hole is formed on the inner surface of the lower end of the mounting column.
The first rotating shaft is attached to the mounting column through a shaft hole.
The drive handle is attached to the outside of the first rotating shaft, and the first synchronous wheel is attached to the inward side of the first rotating shaft.
The second rotating shaft is attached to the inner surface of the upper end of the mounting column, and the second synchronous wheel is attached to the second rotating shaft.
The second synchronous wheel and the first synchronous wheel are connected through a synchronous belt.

The drive handle is manually rotated, the drive handle rotates the first rotating shaft, the rotation of the first rotating shaft rotates the first synchronous wheel, and the rotation of the first synchronous wheel causes the first synchronous wheel and the second synchronous wheel to rotate. The connected synchronization belt is moved.
The fixing mechanism is attached to the inside of the mounting column, and its vertical movement is driven by the synchronous belt.
The LED light bar is mounted on the fixing mechanism, and the upper part of the light bar is formed on the upper surface of the mounting column and appears from the light hole to the outside of the mounting column.

The fixing mechanism includes a moving block, a first fixed block, a second fixed block, a first return spring, a second return spring, a telescopic shell, a moving shell, a third return spring, a limiting bar, a fixed pulley, and a fourth return spring. Includes a first mounting hole, a second mounting hole, a wire, and a second slope.
Two second mounting holes are symmetrically opened on both sides of the moving block.
The rear surface of the moving block has a first mounting hole that penetrates the front and rear, and the front end of the first mounting hole communicates with both the upper and lower sides of the moving block.

The moving block is attached to the inside of the mounting column.
The two telescopic shells are each in two second mounting holes, and there is a second return spring between the back side of each telescopic shell and the second mounting hole.
The role of the second return spring is to return the telescopic shell.
There is a second slope below the first fixed block, and on the second slope, when the moving block moves upward, when the first fixed block matches the position of the first fixed hole, the first fixed block becomes the first. 1 Move into the first fixing hole by the force of the return spring and fit.

When the moving block reaches the highest position, when the drive handle is released, gravity causes the moving block to compress the third return spring by a downward force.
When the moving block reaches the highest position, the two first fixing blocks are completely fitted into the first fixing hole and can support the moving block together with the first fixing hole.

In the present invention, since the second slope is provided under the first fixing block, the first fixing block starts to enter the first fixing hole immediately before the moving block reaches the highest position. ..
Then, when the moving block reaches the highest position, the first fixing block is almost contained in the first fixing hole.
After that, the first fixing block receives the force of the first return spring and completely fits in the first fixing hole.

The two first fixed blocks are each mounted in two telescopic shells, and there is a first return spring between the back side of the first fixed block and the telescopic shell.
The first return spring has a role of returning the first fixed block.
The two first fixing blocks are aligned with the two first fixing holes formed in the mounting column.
The moving shell is mounted in the first mounting hole and can move up and down.
There is a third return spring between the lower surface of the moving shell and the lower surface of the first mounting hole.
The third return spring serves to return the moving shell.
When the moving block is in the highest position, the third return spring is in a slightly compressed state due to the weight of the moving shell.

There are slopes above and below the outside of the second fixed block, and the inclination angle of the lower slope is smaller than the inclination angle of the upper slope.
As a result, while the moving block is receiving a downward force, the second fixing block is easily pushed toward the second fixing hole side and returned to the inside of the moving shell because the slope is provided on the lower side. However, while the moving block is receiving the upward bearing capacity, the upper slope is provided on the upper side, so that the upper slope of the second fixed block abuts on the second fixing hole, so that the second fixed block Is easily pushed out to the fourth return spring.

The second fixed block is mounted inside the moving shell.
There is a fourth return spring between the second fixed block and the moving shell.
The role of the fourth return spring is to give the second fixed block a force to return it to its original position.
The second fixing block fits into the second fixing hole of the stop block attached to the mounting column.
The two limiting bars are symmetrically attached to both sides of the first mounting hole to limit the range of movement of the moving shell.

After the second fixing block of the moving shell is disengaged from the second fixing hole, the moving shell can move the moving block downward by the restriction bar.
The fixed pulley consists of a total of four fixed pulleys arranged in two symmetrical upper and lower stages, and is installed in front of the moving shell.

The two telescopic shells are connected by a laterally extending wire, which extends laterally through a wire hole in the moving block and between fixed pulleys.
The wire extending in the horizontal direction between the two telescopic shells is connected to one end of the wire extending in the vertical direction, and the wire extending in the vertical direction is a symmetrical fixed pulley from the connection point with the wire extending in the horizontal direction. It is connected to the drive plate through the space between them, and the drive plate is fixed to the synchronous belt.

When the moving block moves downward, the wire extending in the vertical direction passes between the two fixed pulleys on the lower left and right.
When the moving block moves upward, the vertically extending wire passes between the two upper left and right fixed pulleys.

When the moving block is in the highest position, there is a gap between the second fixing block and the corresponding second fixing hole.
This gap is evidence that the moving block is supported by the two first fixed blocks at the highest position.
At that time, the two first fixing blocks are fitted into the first fixing holes to stably support the moving block.

There are four guide rails symmetrically on the side of the mounting column.
There are guide blocks at the four corners of the moving block.
The moving block uses four guide blocks to move along the four guide rails.

The lower side of the mounting column has a protective shell that protects the drive handle, which also has a protective door that can be locked.
It is possible to prevent a third party other than the worker from accidentally moving the LED light bar.
A reflector that reflects the light of the LED light bar is attached to the support rod at the top of the mounting column.
There are symmetrically two third guide tanks on both side surfaces on the front side of the first mounting hole provided in the moving block.

Two avoidance ports are formed on the back side of the drive plate.
Since the avoidance port is formed, when the drive plate moves upward, it does not hit the four fixed pulleys.
There are two symmetrical fifth guide blocks on both sides of the drive plate on the side with the avoidance opening.
The drive plate is installed in the moving block by a combination of two fifth guide blocks and two third guide tanks.

A wire extending in the vertical direction, which is different from the wire connecting the two telescopic shells, is connected to one end of the fifth guide block of the drive plate.
The end of the drive plate connects to the synchronous belt.
The movement of the drive plate is restricted by the combination of the two fifth guide blocks and the two third guide tanks.
As a result, even if the drive plate is shaken by the synchronous belt, it is not affected by the movement of the synchronous belt.

Two first guide tanks are symmetrically formed on both side surfaces on the inner side of the first mounting hole provided in the moving block.
On the side of the moving shell, there are symmetrically two first guide blocks.
The movement of the moving shell is restricted in the moving block by the combination of the two first guide blocks and the two first guide tanks.

Two fourth guide tanks are symmetrically formed on both side surfaces in the moving shell.
There are two symmetrical second guide blocks on both sides of the second fixed block.
The movement of the second fixed block in the moving shell is restricted by the combination of the two second guide blocks and the two fourth guide tanks.

Two second guide tanks are symmetrically formed on both side surfaces of the second mounting hole provided in the moving block.
There are symmetrically two third guide blocks on both sides of the telescopic shell.
The telescopic shell is restricted in movement within the moving block by the combination of the two third guide blocks and the two second guide tanks.

Two fifth guide tanks are symmetrically opened on both sides of the telescopic shell.
There are two symmetrical fourth guide blocks on both sides of the first fixed block.
The movement of the first fixed block in the telescopic shell is restricted by the combination of the two fourth guide blocks and the two fifth guide tanks.

The first return spring, the second return spring, the third return spring, and the fourth return spring are in the natural length state when the moving block is in the highest position.
Compared with the conventional LED lighting device, the LED lighting device of the present invention manually turns the drive handle, controls the vertical movement of the fixing mechanism that supports the LED light bar through the synchronous wheel, and replaces the LED light bar.

Furthermore, when the fixing mechanism and the LED light bar are in the highest position, the two first fixing blocks are fitted into the two first fixing holes, and the two first fixing holes stably support the moving block. Has been done.
When the fixing mechanism moves downward, the downward traction force is not transmitted to the moving block via the fixing pulley, so that the frictional force between the two first fixing blocks and the two first fixing holes does not increase.
Therefore, the two first fixing blocks smoothly come off from the first fixing hole, and the fixing mechanism smoothly moves downward.

External view of the main body Schematic configuration diagram showing the internal structure of the main body Schematic configuration diagram showing the mounting state of the fixing mechanism Schematic configuration of the first fixing block and the first fixing hole Schematic configuration of the second fixing block and the second fixing hole Schematic configuration diagram showing the operating principle of the second fixed block Schematic configuration of mounting columns Schematic configuration diagram showing the mounting state of the stop block Schematic configuration of the protective shell Schematic configuration diagram showing the mounting state of the synchronous belt Schematic configuration diagram showing the connection state of the drive plate and the synchronization belt Schematic configuration of the fixing mechanism External view of fixing mechanism Schematic configuration diagram showing the mounting state of the telescopic shell Schematic configuration diagram showing the mounting state of the moving shell Schematic configuration of the moving block Schematic configuration of the first mounting hole Schematic configuration of the second mounting hole Schematic configuration diagram showing the internal structure of the moving block Schematic configuration diagram showing the mounting state of the second fixed block Schematic configuration of the moving shell Schematic configuration of the second fixed block Schematic configuration diagram showing the mounting state of the first fixed block Schematic configuration of the telescopic shell Schematic configuration of the first fixed block Schematic configuration of the drive plate

Examples of the present invention will be described with reference to the drawings.
The examples described below are examples of the present invention, not all examples.
Based on the examples of the present invention, all examples that can be easily conceived by those skilled in the art belong to the scope of protection of the present invention.

Hereinafter, a specific method for carrying out the present invention will be described in more detail with reference to the drawings.
The following examples are used to explain the present invention, but do not limit the scope of the present invention.

As shown in FIGS. 1 and 2, the LED lighting device according to the present embodiment includes an LED light bar 1, a mounting column 2, a fixing mechanism 4, a synchronization belt 5, a drive handle 16, a first synchronization wheel 17, and a first rotation shaft. 18, the second synchronous wheel 19, and the second rotating shaft 20 are included.
As shown in FIGS. 7 and 8, the mounting column 2 is hollow.
As shown in FIG. 8, there are symmetrically two first fixing holes 12 on the inner surface of the mounting column 2.

The first fixing hole 12 fixes the moving block 6 in cooperation with the two first fixing blocks 7 when the moving block 6 is in the highest position.
In this fixed state, the two first fixing blocks 7 are fitted into the corresponding first fixing holes 12, so that the two first fixing holes 12 are stably supported so that the moving block 6 does not fall. To do.

The two first fixing holes 12 are provided in the upper part of the mounting column 2.
A stop block 11 is attached to the side surface of the mounting column 2 without the first fixing hole 12.
The stop block 11 has a second fixing hole 14, and the role of the second fixing hole 14 is as follows.
When the synchronous belt 5 pulls the wire 40 downward, the wire 40 gives the moving block 6 a downward traction force.

At that time, since the moving block 6 is at the highest position, the two first fixing blocks 7 are fitted into the two first fixing holes 12.
When pulled by the wire 40 in that state, the downward vertical force received by the moving block 6 becomes stronger due to the traction force of the wire 40, and the frictional force between the two first fixing blocks 7 and the first fixing hole 12 also becomes stronger.

Then, the downward force received by the two first fixing blocks 7 from the first fixing hole 12 becomes stronger, and the resistance force that the telescopic shell 26 is pulled by the wire 40 also becomes stronger.
Further, the greater the traction force of the wire 40, the greater the resistance to which the telescopic shell 26 is pulled by the wire 40.

In this state, since the two first fixing blocks 7 are fitted in the two first fixing holes 12, the moving block 6 does not move downward.
However, since the wire 40 passes through the fixed pulley 30 and the fixed pulley 30 is attached to the moving shell 28, the wire 40 transmits the traction force to the moving shell 28 through the fixed pulley 30 so that the moving shell 28 is directed downward. Move to.
As a result, the moving shell 28 moves downward, and the second fixed block 8 also moves downward.

At that time, when the lower slope of the second fixing block 8 hits the second fixing hole 14, the second fixing hole 14 gives an upward supporting force to the second fixing block 8.
Since the inclination angle of the lower slope of the second fixed block 8 with respect to the horizontal direction is small, the second fixed block 8 does not easily return to the moving shell 28 side from the second fixed hole 14.
In this state, the second fixing hole 14 provides an upward bearing capacity to the moving shell 28 via the second fixing block 8.

Since its bearing capacity offsets most of the downward traction of the wire 40, when the wire 40 is pulled downward, it is transmitted downward between the two first fixing blocks 7 and the two first fixing holes 12. The traction force is reduced, and the resistance of the telescopic shell 26 to the traction force of the wire 40 is also reduced.
If the wire 40 is pulled in this state, the telescopic shell 26 can be moved through the wire 40.
A shaft hole 9 is formed on the inner surface of the lower end of the mounting column 2.

As shown in FIG. 3, the first rotating shaft 18 is attached to the mounting column 2 through the shaft hole 9 of the mounting column 2.
As shown in FIG. 10, the drive handle 16 is attached to the outside of the first rotating shaft 18, and the first synchronous wheel 17 is attached to the inside of the first rotating shaft 18.
The second rotating shaft 20 is attached to the inner surface of the upper end of the mounting column 2, and the second synchronous wheel 19 is attached to the second rotating shaft 20.

The second synchronous wheel 19 and the first synchronous wheel 17 are connected to each other through the synchronous belt 5.
The drive handle 16 is manually rotated, and the drive handle 16 rotates the first rotation shaft 18.
The first rotation shaft 18 rotates the first synchronization wheel 17, and the first synchronization wheel 17 moves the synchronization belt 5 to which the first synchronization wheel 17 and the second synchronization wheel 19 are connected.

As shown in FIG. 3, the fixing mechanism 4 is installed inside the mounting column 2 and moves up and down in the mounting column 2 by the drive of the synchronous belt 5.
As shown in FIG. 4, the LED light bar is attached to the fixing mechanism 4, and the upper end thereof appears outside the mounting column 2 through the light hole 13 opened on the top surface of the mounting column 2.

As shown in FIG. 12, the fixing mechanism 4 includes a moving block 6, a first fixed block 7, a second fixed block 8, a first return spring 24, a second return spring 25, a telescopic shell 26, a moving shell 28, and a third. A return spring 28, a limiting bar 29, a fixed pulley 30, a fourth return spring 31, a first mounting hole 33, a second mounting hole 36, a wire 40, and a second slope 47 are included.

As shown in FIG. 16, two second mounting holes 36 are symmetrically provided on both side surfaces of the moving block 6.
As shown in FIG. 17, the moving block 6 is formed with a first mounting hole 33 that penetrates back and forth, and the front end of the first mounting hole 33 communicates with both the upper and lower surfaces of the moving block 6.

As shown in FIG. 4, the moving block 6 is attached to the inside of the mounting column 2.
As shown in FIG. 14, the two telescopic shells 26 are each provided in the two second mounting holes 36.
There is a second return spring 25 between the back side of the two telescopic shells 26 and the second mounting hole 36.
The role of the second return spring 25 is to give the telescopic shell 26 a force to return it to its original position.

As shown in FIG. 25, there is a second slope 47 below the two first fixed blocks 7.
When the two first fixing blocks 7 come into contact with the first fixing hole 12 when the moving block 6 moves upward, the force of the first return spring 24 enters and fits into the first fixing hole 12.

When the moving block 6 moves to the highest position and the drive handle 16 is released, the moving block 6 gains a downward force due to gravity.
The third return spring 28 is in a compressed state.
When the moving block 6 reaches the highest position and moves downward, the two first fixed blocks 7 can completely fit into the first fixing hole 12 and fully support the moving block 6.

In this embodiment, since the second slope 47 is provided below the two first fixed blocks 7, the moving block 6 is fixed to the first position immediately before reaching the highest position. It will be in a state where it is about to fit in the hole.
Then, when the moving block 6 reaches the highest position, the first fixing block 7 is substantially contained in the first fixing hole 12.

The second slope 47 on the upper side of the first fixing block 7 is in contact with the first fixing hole 12.
As a result, the first fixing block 7 can be fitted into the first fixing hole 12 to support the moving block.
When the moving block 6 moves downward, the third return spring 28 is in a slightly compressed state.

As shown in FIG. 23, each of the two first fixing blocks 7 is mounted in two telescopic shells 26, and there is a first return spring 24 between the back side thereof and the telescopic shell 26.
The role of the first return spring 24 is to return the first fixed block 7.

As shown in FIG. 4, the two first fixing blocks 7 are aligned with the two first fixing holes 12 formed in the mounting column 2.

As shown in FIG. 15, the moving shell 28 is mounted in the first mounting hole 33, and there is a third return spring 28 between the lower surface of the moving shell 28 and the lower surface of the first mounting hole 33.
The role of the third return spring 28 is to return the moving shell 28.
When the moving block 6 is in the highest position, the third return spring 28 is in a slightly compressed state due to the gravity of the moving shell 28.

As shown in FIG. 22, there are slopes above and below one end of the second fixed block 8, and the inclination angle based on the horizontal direction of the lower slope is smaller than the inclination angle based on the horizontal direction of the upper slope.
As a result, while the moving block 6 is receiving a downward force, the second fixed block 8 is easily pushed into the second fixing hole 14 by the lower slope of the second fixed block 8 to move the shell 28. Although it does not return to the inside, while the moving block 6 receives the upward bearing capacity, the upper slope of the second fixed block 8 abuts on the second fixed hole 14, so that the second fixed block 8 abuts. Is easily pushed out to the fourth return spring 31.

As shown in FIG. 20, the second fixed block 8 is mounted in the moving shell 28, and there is a fourth return spring 31 between the second fixed block 8 and the moving shell 28.
The role of the fourth return spring 31 is to give the second fixed block 8 a force to return it to its original position.
As shown in FIG. 5, the second fixing block 8 fits into the second fixing hole 14 of the stop block 11 attached to the mounting column 2.
The two limiting bars 29 are symmetrically attached to both side surfaces of the first mounting hole 33.
As shown in FIG. 15, the two restriction bars 29 limit the range of movement of the moving shell 28.

When the second fixing block 8 in the moving shell 28 is disengaged from the second fixing hole 14, the moving shell 28 can move the moving block 6 downward by the limiting bar 29.
As shown in FIG. 19, a pair of symmetrical fixed pulleys 30 is attached to the front side of the moving shell 28 in two upper and lower stages.

The two telescopic shells 26 are connected by a wire 40 extending in the lateral direction.
The laterally extending wire 40 extends between the fixed pulleys 30 through the wire holes 38 of the moving block 6.
The wire 40 extending in the horizontal direction between the two telescopic shells 26 is connected to one end of the wire 40 extending in the vertical direction.
The wire 40 extending in the vertical direction is connected to the drive plate 22 from the connection point with the wire 40 extending in the horizontal direction through between the symmetrical fixed pulleys 30, and the drive plate 22 is fixed to the synchronous belt 5.

When the moving block 6 moves downward, the wire 40 extending in the vertical direction passes between the two fixed pulleys 30 on the left and right of the lower stage.
When the moving block 6 moves upward, the wire 40 extending in the vertical direction passes between the two fixed pulleys 30 on the left and right of the upper stage.

As shown in FIG. 6, when the moving block 6 is in the highest position, there is a gap between the second fixing block 8 and the second fixing hole 14.
The gap is created when the moving block 6 is supported by two first fixed blocks 7.
When the moving block 6 is in the highest position, the two first fixing blocks 7 are fitted into the first fixing holes 12, so that the two first fixing holes 12 stably support the moving block 6.

The effects of the present invention according to the above examples are as follows.
The LED lighting device is operated by manually turning the drive handle 16.
The drive handle 16 moves the fixing mechanism 4 that supports the LED light bar up and down through the synchronous wheels.

As a result, the LED light bar is replaced.
Further, when the fixing mechanism 4 and the LED light bar of the present invention are in the highest positions, the two first fixing blocks 7 are fitted into the two first fixing holes 12, so that the two first fixing holes 12 are moving blocks. Supports 6 stably.

At the same time, when the fixing mechanism 4 moves downward, the downward traction force is not transmitted to the moving block through the fixing pulley 30.
Therefore, the frictional force between the two first fixing blocks 7 and the two first fixing holes 12 does not become strong, so that the two first fixing blocks 7 smoothly come off from the first fixing holes 12.
As a result, the fixing mechanism 4 moves smoothly downward.

As shown in FIG. 7, there are four guide rails 10 symmetrically on both side surfaces in the mounting column 2.
As shown in FIG. 16, there are guide blocks 35 at the four corners of the moving block 6.
As shown in FIG. 3, the moving block 6 uses the four guide blocks 35 to move the mounting columns 2 along the four guide rails 10.

As shown in FIGS. 1 and 9, a protective shell for protecting the drive handle 16 is attached to the lower side surface of the mounting column 2, and the protective shell 3 also has a protective door 15 that can be locked.
It is designed so that a third party other than the worker cannot accidentally move the LED light bar 1.

As shown in FIG. 1, a reflector 21 that reflects the light of the LED light bar 1 is attached on the support rod 23 at the upper part of the mounting column 2.
As shown in FIG. 17, there are symmetrically two third guide tanks 37 on both side surfaces on the front side of the first mounting hole 33 provided in the moving block 6.

As shown in FIG. 26, two avoidance ports 50 are formed at one end of the drive plate 22.
Since the avoidance port 50 is formed, when the drive plate 22 moves upward, it does not hit the four fixed pulleys 30.
There are two symmetrical fifth guide blocks 49 on both sides of the drive plate 22 on the side where the avoidance port 50 is located.

As shown in FIGS. 12 and 13, the drive plate 22 is installed in the moving block 6 by a combination of two fifth guide blocks 49 and two third guide tanks 37.
A wire 40 extending in the vertical direction, which is different from the wire connecting the two telescopic shells 26, is connected to one end of the fifth guide block 49 of the drive plate 22.
As shown in FIG. 11, the end portion of the drive plate 22 is connected to the synchronous belt.
The movement of the drive plate 22 is restricted by the combination of the two fifth guide blocks 49 and the two third guide tanks 37.

As a result, even if the drive plate 22 is shaken by the synchronous belt 5, it is not affected by the movement of the synchronous belt 5.
Two first guide tanks 32 are symmetrically formed on both side surfaces on the inner side of the first mounting hole 33 provided in the moving block 6.
On the side surface of the moving shell 28, there are symmetrically two first guide blocks 41.
The movement of the moving shell 28 in the moving block 6 is restricted by the combination of the two first guide blocks 41 and the two first guide tanks 32.

As shown in FIG. 21, two fourth guide tanks 42 are symmetrically formed on both side surfaces in the moving shell 28.
As shown in FIG. 22, there are symmetrically two second guide blocks 43 on both side surfaces of the second fixed block 8.
As shown in FIG. 20, the movement of the second fixed block 8 in the moving shell 28 is restricted by the combination of the two second guide blocks 43 and the two fourth guide tanks 42.

As shown in FIGS. 16 and 18, two symmetrical second guide tanks 34 are formed on both side surfaces of the second mounting hole 36 provided in the moving block 6.
As shown in FIG. 24, there are two symmetrical third guide blocks 45 on both side surfaces of the telescopic shell 26.
As shown in FIG. 14, the telescopic shell 26 is restricted in movement in the moving block 6 by the combination of the two third guide blocks 45 and the two second guide tanks 34.

As shown in FIG. 24, two symmetrical fifth guide tanks 46 are provided on both side surfaces in the telescopic shell 26.
As shown in FIG. 25, there are two symmetrical fourth guide blocks 48 on both side surfaces of the first fixed block 7.

As shown in FIG. 23, the movement of the first fixed block 7 in the telescopic shell 26 is restricted by the combination of the two fourth guide blocks 48 and the two fifth guide tanks 46.
The first return spring 24, the second return spring 25, the third return spring 28, and the fourth return spring 31 are in a natural length state when the moving block 6 is in the highest position.

The method of using the LED lighting device according to this embodiment is as follows.
When using the LED light, if the LED light is broken and needs to be replaced, the drive handle 16 is first turned to move the synchronization belt 5.
The synchronous belt 5 pulls the wire 40 downward via the drive plate 22.
The wire 40 then pulls the moving shell 28 downward.

Due to the second fixing block 8 and the second fixing hole 14 attached to the moving shell 28, the second fixing block 8 receives almost all the downward traction force of the wire 40.
The second fixed block 8 moves into the moving shell 28 by its traction force.
If the wire 40 is pulled in that state, the wire 40 will pull the telescopic shell 26.

The telescopic shell 26 moves the first fixed block 7 by the combination of the fourth guide block 48 and the fifth guide tank 46.
First, the portion where the first fixing block 7 fits in the first fixing hole 12 is separated.
Next, the frictional force between the second slope 47 of the first fixing block 7 and the first fixing hole 12 becomes stronger.
Further, when the wire 40 is pulled downward, the second slope 47 of the two first fixing blocks 7 gradually separates from the first fixing hole 12.

When the wire 40 is pulled after the second fixing block 8 is completely separated from the second fixing hole 14, the moving shell 28 moves downward.
The moving shell 28 abuts on the limiting bar 29, and the limiting bar 29 moves the moving block 6 downward.
The moving block 6 moves downward together with the LED light bar.
The LED light bar can be moved down and replaced.

After the replacement is completed, the drive handle 16 is turned in the opposite direction to move the synchronization belt 5 in the opposite direction.
The synchronous belt 5 pulls the wire 40, and the wire 40 pulls the moving block 6 upward via the two fixed pulleys 30 on the upper stage.
When the second fixing block 8 in the moving shell 28 comes into contact with the second fixing hole 14 while the moving block 6 is moving upward, the second fixing block 8 is moved to the second fixing hole by the force of the fourth return spring 31. It is returned to 14.

At the same time, when the second slope 47 of the first fixing block 7 comes into contact with the first fixing hole 12, the first fixing block 7 begins to return into the first fixing hole 12 by the force of the first return spring 24.
When the moving block 6 has completely moved to the highest position, when the drive handle 16 is stopped, the moving block 6 moves downward due to gravity.
During the downward movement, the telescopic shell 26 moves in the direction of the first fixing hole 12 by the force of the second return spring 25.

Along with that, the first fixing block 7 in the telescopic shell 26 also moves and completely fits in the first fixing hole 12.
This will return you to the initial position.

The above examples are not limited examples of the present invention, and those skilled in the art can make improvements and modifications based on the essence of the present invention.
The accompanying drawings of the present invention are diagrams illustrating an embodiment of the present invention for understanding structural operation.
The specific product structure and proportion size can be confirmed together with the conventional technology according to the usage environment.

1 LED light bar
2 Mounting pillar
3 protective shell
4 Fixing mechanism
5 Sync belt
6 moving block
7 1st fixed block
8 2nd fixed block
9 Shaft hole
10 guide rail
11 Stop block
12 1st fixing hole
13 light holes
14 2nd fixing hole
15 Protective door
16 drive handle
17 First synchronous wheel
18 1st rotation axis
19 Second synchronous wheel
20 Second axis of rotation
21 reflector
22 Drive plate
23 Support rod
24 1st return spring
25 Second return spring
26 Telescopic shell
27 moving shell
28 Third return spring
29 Limit bar
30 Fixed pulley
31 4th return spring
32 1st guide tank
33 1st mounting hole
34 2nd guide tank
35 Guide block
36 2nd mounting hole
37 3rd guide tank
38 wire hole
40 wire
41 1st guide block
42 4th guide tank
43 2nd guide block
45 3rd guide block
46 5th guide tank
47 Second slope
48 4th guide block
49 5th guide block
50 Avoidance

Claims (3)

It consists of an LED light bar, a mounting column, a fixing mechanism, a synchronization belt, a drive handle, a first synchronization wheel, a first rotation shaft, a second synchronization wheel, and a second rotation shaft.
The mounting column is hollow, with two symmetrical first fixing holes at the top of the inner surface of the mounting column.
A stop block is attached to the side surface of the mounting column without the first fixing hole, and the stop block has a second fixing hole.
A shaft hole is formed on the inner surface of the lower end of the mounting column.
The first rotating shaft is attached to the mounting column through the shaft hole,
The drive handle is attached to the outside of the first rotating shaft,
The first synchronous wheel is attached to the inward side of the first rotating shaft,
The second rotating shaft is attached to the inner surface of the upper end of the mounting column.
The second synchronous wheel is attached to the second rotating shaft,
The second synchronous wheel and the first synchronous wheel are connected through a synchronous belt, and are connected.
The fixing mechanism is mounted inside the mounting column, its movement is driven by a synchronous belt,
The LED light bar is mounted on the fixing mechanism,
The upper part of the light bar emerges outside the mounting column through the light holes formed on the upper surface of the mounting column.
The fixing mechanism includes a moving block, a first fixed block, a second fixed block, a first return spring, a second return spring, a telescopic shell, a moving shell, a third return spring, a limiting bar, a fixed pulley, and a fourth return spring. It consists of a first mounting hole, a second mounting hole, a wire, and a second slope.
Two second mounting holes are symmetrically formed on both sides of the moving block.
On the back surface of the moving block, there is a first mounting hole that penetrates the front and back, and the front end of the first mounting hole communicates with both the upper and lower sides of the moving block.
The moving block is attached to the inside of the mounting column,
The two telescopic shells are each in two second mounting holes,
There is a second return spring between the back of each telescopic shell and the second mounting hole.
A second slope is formed on the lower side of the first fixed block.
The two first fixed blocks are each placed in two telescopic shells,
There is a first return spring between the back of the two first fixed blocks and the telescopic shell.
The two first fixing blocks are a set with the two first fixing holes provided on the inner side surface of the mounting column.
The moving shell is installed in the first mounting hole , and there is a third return spring between its lower surface and the lower surface of the first mounting hole .
The upper and lower sides of one end of the second fixed block are formed on a slope, and the inclination angle of the lower slope with respect to the horizontal direction is smaller than the inclination angle of the upper slope with respect to the horizontal direction.
The second fixed block is installed inside the moving shell, and there is a fourth return spring between the back side and the moving shell.
The second fixing block is a set with the second fixing hole provided in the stop block of the mounting column.
Two limiting bars are symmetrically provided on both sides of the first mounting hole to limit the movement of the moving shell.
The four fixed pulleys are installed at the front end of the moving shell symmetrically in two stages, upper and lower.
The two telescopic shells are connected by a wire that extends laterally.
The wire passes between the fixed pulleys through the wire holes in the moving block and
A wire extending laterally between the two telescopic shells is connected to one end of the wire extending vertically.
The wire extending in the vertical direction is connected to the drive plate from the connection point with the wire extending in the horizontal direction through between the symmetrical fixing pulleys, and is fixed to the synchronous belt .
A lighting device characterized in that when the moving block is in the highest position, there is a gap between the second fixed block and the corresponding lower surface of the second fixed hole.
There are four symmetrical guide rails on both sides of the mounting column.
There are guide blocks at the four corners of the moving block,
The moving block uses four guide blocks to move along the four guide rails,
A protective shell is attached to the lower side of the mounting column to protect the drive handle.
The lighting device according to claim 1, wherein the protective shell is provided with a protective door that can be locked.
On both sides of the front side of the first mounting hole provided in the moving block,
There are two symmetrical third guide tanks,
There are two avoidance ports on the back side of the drive plate,
There are two symmetrical fifth guide blocks on both sides of the drive plate on the side with the avoidance opening.
The drive plate is provided on the moving block by a combination of two fifth guide blocks and two third guide tanks.
A wire extending in the vertical direction, which is different from the wire extending in the horizontal direction between the two telescopic shells, is connected to one end of the fifth guide block of the drive plate.
One end on the outside of the drive plate is connected to the synchronization belt,
Two symmetrical first guide tanks are provided on both side surfaces on the back side of the first mounting hole of the moving block.
Two symmetrical first guide blocks are attached to both sides of the moving shell.
The lighting device according to claim 1, wherein the moving shell is attached to the moving block by a combination of two first guide blocks and two first guide tanks.

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