KR102054769B1 - Vacuum Cleaner Foldable Pipe - Google Patents

Abstract

The present invention relates to a stretch pipe having a stretchable length, including an inner pipe, an outpipe, and a locking device, wherein the inner pipe is inserted into the outpipe to be slidably connected, and one end of the outpipe is provided with a locking device. The locking device includes a sliding cover plate and a base, wherein the base projects from the inside to the outside through a mounting groove formed on an end pipe of the outpipe end; A sliding cover plate is movably connected to the base in an axial direction; The sliding cover plate covers the upper end of the base and provides a kind of expansion pipe configured to surround the area corresponding to the base on the outer pipe outer contour, and by configuring a compact and simple locking device, the user In addition to improving comfort and convenience, the production and manufacturing capabilities are also enhanced.

Description

Vacuum Cleaner Foldable Pipe {Vacuum Cleaner Foldable Pipe}

The present invention relates to a kind of connecting pipe, and more particularly to a vacuum cleaner expansion pipe connected between a nozzle and a hose applied to a kind of cleaner.

At present, there are many kinds of general expansion pipes on the market, and also the structure of expansion locks of expansion pipes are different. Existing locking devices have various types, and most of them are slow to operate. , Not smooth, uncomfortable.

1 is a perspective view of a sleeve-type expansion pipe that is currently commonly used. As shown, this is a sleeve-type telescopic pipe commonly used on cleaners, which allows the user to grasp the mounted sleeve while the palm of one hand wraps around the entire circumferential surface of the outpipe 2, A portion of the palm needs to be grasped and supported by the outer surface of the outpipe (2), and then the palm grasping the sleeve pushes the sleeve forward with the support of the portion of the palm held by the outer surface of the outpipe (2) Or by pulling back the sleeve to unlock the locking device 3. That is, the inner pipe 1 is in a state in which the inner pipe 1 is movable. At this time, the other hand grasps the inner pipe 1 and pulls it out, or inserts it in to realize the expansion and contraction of the expansion pipe. The expansion pipe locking device 3 is fixedly supported on the circumferential surface of the outpipe 2. And a sleeve that slides back and forth relative to the support member on the outer contour of the member and the support member. The support member and the sleeve are both bushing structure having a constant wall thickness. Therefore, this sleeve type locking device (3) has a double bushing structure is installed to surround the outer contour of the outpipe on a portion of the end of the outpipe (2), so that the expansion pipe is inevitably in the circumferential direction of the outpipe circumferential surface The thickness is increased to a considerable thickness. Therefore, when the user grips and manipulates the sleeve, the sleeve is formed to a high thickness on the circumferential surface of the outpipe 2, thereby inevitably becoming dull to sense that the operation is not smooth. It causes the inconvenience of operation. In addition, in terms of ergonomics, the longer the use time brings fatigue to the user's palm, bringing inconvenience to the user.

Figure 2a is a perspective view of a conventional button-type expansion pipe at present. As shown in the drawing, there is another type of button type expansion pipe which is commonly used at present, and this expansion pipe is used by the user to grasp the locking device with one hand, and at the same time, push the button with the thumb to unlock the locking device. To realize. That is, the inner pipe 1 is formed to be movable in the out pipe 2. At this time, by holding the inner pipe (1) with the other hand and pulling it out or inserting it in or out to realize the expansion and contraction of the expansion pipe, the locking device (3) of the expansion pipe for the user, locking in only one direction By driving the device, that is, by simply pushing the button, lack of smoothness, and by pushing the drive by the thumb alone, it is easy to cause fatigue, thus bringing inconvenience to the user . In addition, the expansion pipe used on the vacuum cleaner is a pipeline through which a kind of air flows, and thus, it is necessary to ensure the sealability between the inner pipe 1 and the out pipe 2 during the expansion process, and the high vacuum suction force of the cleaner is other than the pipeline. It should be prevented from leaking, and the phenomenon of inferior cleaning efficiency occurs.

In addition, current conventional expansion pipes, when the user stretches or shortens the expansion pipe, as described above, while holding the locking device with one hand, and at the same time, additional release force must be applied separately, that is, to the sleeve Push / pull force or push force to the button, such a grip and push / pull force or a combination of the two forces of the grip and push force plus the pull or insert to the inner pipe (1) of the other hand Torsional force is generated between the inner pipe 1 and the outpipe 2 due to the reaction force of the force. If this is not suppressed against the torsional force, the locking does not become firm. In addition, in the situation of the expansion pipe used on the cleaner, the airtightness between the inner pipe 1 and the outpipe 2, that is, the airtightness of the airflow is easily destroyed. Therefore, the vacuum forming capacity of the vacuum cleaner vacuum motor is wasted in vain due to poor airtightness, and finally, the vacuum cleaner efficiency is reduced.

Figure 2b is a cross-sectional view showing a locking state of the button type expansion pipe locking device of the current prior art, Figure 2c is a cross-sectional view of the unlocked state of a button type expansion pipe locking device of the current prior art. As shown, the locking device 3, which is one of the current prior arts, is composed of a driving plate 31, a driving plate 32, a support bushing 33, a spring 34, and a locking block 35. The driving plate 31 is connected to the driving plate 32 through the hook, the driving plate 32 is installed on the support bushing 33 so as to be movable, and the support bushing 33 is the outpipe 2. One end of the outpipe 2 is inserted by being connected to one end of the end and folding the edge of the end.

In the course of operation, when the operator adds thrust in the direction of the hollow arrow shown in FIG. 2C with one hand, the driving plate 31 leads the driving plate 32 to overcome the action of the compressive elastic force of the spring 34. , Move in the direction of the solid arrow. At this time, the driving rod installed at the lower end of the driving plate 32 is in a state of releasing the pressure on the locking block 35, and thus the locking block 35 is moved upward along the driving hole formed on the support bushing 33, Therefore, the lock block 35 releases the lock state of the locking protrusion formed on the inner pipe, and smoothly moves between the inner pipe 1 and the out pipe 2.

When the thrust applied by the operator's hand is removed, the drive plate 32 is moved in the direction of the solid arrow in Fig. 2b, under the action of the spring's elastic recovery force, at which time the drive bar at the bottom of the drive plate 32 is a lock block. Presses 35 to move downward, so that the driving block moves downward along the driving hole, thereby locking the locking projection installed on the inner pipe, so that the locking between the inner pipe 1 and the out pipe 2 Is realized.

However, such a locking device must be driven in the direction indicated by the hollow arrow to release the lock between the inner pipe and the outpipe according to the existing operation, there is a restriction in use and inconvenient to use. In addition, the driving plate 31 and the driving plate 32 need to be assembled separately, and will affect the life of the spring.

3, on the basis of the original locking surface formed on the mating surface in contact with the locking surface 10 in the inner pipe 1, whether the current conventional sleeve-type expansion pipe or button-type expansion pipe, The torsion preventing groove 30 is further formed, and the torsion preventing groove 30 is combined with the protrusion installed in the locking device to prevent the inner pipe 1 from being torsionally rotated in the outpipe 2. However, this separately installed torsional rotation prevention device complicates the structure of the expansion pipe as a whole, and thus, one step of processing the prevention groove is added during the processing of the inner pipe 1, thereby increasing the processability. Lowers production efficiency. In addition, in the case of the expansion pipe used in the vacuum cleaner, even if the torsion prevention device installed separately, that is, the occurrence of leakage in the coupling portion of the torsion prevention groove 30 and the projection.

In addition, by installing a structure corresponding to the inner pipe torsion preventing groove 30 in the locking device 3 separately, it occupies the space of the locking device, and the volume of the locking device becomes large and does not become compact. The comfort of using is reduced, and in advancing the structure in order to reduce the volume, there are also problems that the expansion pipe lock operation is slowed and the operation is easily lost.

The present invention is conceived to solve the technical problems existing in the above-described conventional technology, and provides a kind of expansion pipe that can solve the inconvenience that the user feels during use.

The present invention provides a kind of expansion pipe that is more stable and free of operation.

The present invention provides a kind of expansion pipe which realizes torsional rotation prevention with a simpler structure.

The present invention also provides a kind of expansion pipe that is simple and convenient to assemble.

Technical solutions employed by the present invention for realizing the above object include an inner pipe, an outpipe, and a locking device, wherein the inner pipe is slidably connected in the outpipe, and is connected to one end of the outpipe. In the expansion pipe is equipped with the locking device, The locking device, the sliding cover plate; Base; A spring installed in a space formed between the sliding cover plate and the base; And a braking block vertically moving up and down in a driving hole installed on the base, wherein the upper end of the base protrudes upward through a mounting groove formed at one end of the outpipe from the inside to the outside, and the upper surface of the base Guide hooks are installed symmetrically about the center axis of the outpipe with a symmetrical axis, and a sliding hook is installed on the bottom of the sliding cover plate, and the sliding hook of the sliding cover plate is horizontal along the guide hook formed on the upper surface of the base. When sliding, the sliding cover plate is capable of sliding relative movement in the axial direction with respect to the base, the sliding cover plate covers the upper end of the base, the area corresponding to the base on the outpipe outer contour Is configured to wrap, the sliding cover plate is gripped Further comprising a drive rod installed on the bottom of the drive rod is provided with a braking surface by a horizontal plane formed between the driving surface and the inclined surface by the inclined surface of the end, the braking surface is coupled to the braking surface of the braking block The driving surface is configured to operate in conjunction with the driving surface of the brake block, wherein the inclined surface formed before and after the upper surface forms the driving surface, and the horizontal surface between the inclined surface forms the braking surface. Provide expansion pipe.

In addition, the present invention includes an inner pipe, an outpipe, and a locking device, wherein the inner pipe is slidably connected in the outpipe, and in the expansion pipe in which the locking device is mounted at one end of the outpipe, The locking device, the sliding cover plate; Base; A spring installed in a space formed between the sliding cover plate and the base; And a braking block vertically moving up and down in a driving hole installed on the base, wherein the base includes: a driving hole formed at a center thereof to vertically move the braking block; A pair of guide hooks formed on both sides of the driving hole to guide the sliding hook formed on the bottom surface of the sliding cover plate in the axial direction; A spring seating groove formed at one side of the driving hole to seat the spring; And a pair of support wings which are formed to be symmetrically paired forward and backward on both sides of the driving hole so as to be in contact with the inner wall of the outpipe, including one end of the outpipe from the inside of the outpipe to the outside. Protruding upward through the mounting groove formed in the, the sliding cover plate covers the upper end of the base, and provides an expansion pipe, characterized in that configured to surround the area corresponding to the base on the outer pipe outer contour. .

As described above, the present invention realizes the expansion and contraction operation of the expansion pipe through a simple and compact locking device, thereby improving the comfort and convenience during the user use process. Further, in the current conventional art of the present invention, the locking surface on which the locking projections already present are installed is slightly expanded in the circumferential direction to form a guide surface, and then the structure of the locking projections already has its own structure. By using the combination to realize the torsional rotation prevention function realized by separately installing the torsional rotation prevention groove on the other side in contact with the locking surface in addition to the locking surface in the prior art, the torsional rotation prevention function can be realized without increasing the machining process, and thus It is possible to effectively increase the production and processing efficiency, and the present invention also provides a stable connection of the expansion pipe operation due to the precise connection assembly relationship between each component, and is generated due to the operation of a number of conventional parts together during the operation process. Remove the rest of the noise and, therefore, the user Enhancing the convenience for a sense of comfort in the process, and also, at the same time ensuring the strength of the assembly, and the structure simplified as much as possible, thereby reducing the cost to a minimum.

1 is a perspective view of a conventional sleeve type expansion pipe.
Figure 2 is a perspective view of a conventional push and pull button expansion pipe.
3 is a partial perspective view of a first expansion pipe of a conventional expansion pipe.
Figure 4 is a perspective view of the gripping expansion pipe of the present invention.
Figure 5 is an exploded perspective view of the grip type expansion pipe locking device of the present invention.
Figure 6 is a perspective view of the connection relationship of each of the gripping expansion pipe component of the present invention.
Fig. 7A is an axial partial sectional view showing a connection relationship between components in the expansion pipe locked state of the present invention.
Fig. 7B is an axial partial cross sectional view showing a connection relationship between components in the expansion pipe unlocked state of the present invention.
8A and 8B are perspective views of a first expansion pipe of the expansion pipe of the present invention.
9 is a longitudinal sectional view showing a state in which the base and the first expansion pipe are engaged in the locking device.
10 is a longitudinal sectional view showing a state in which a support and a first expansion pipe are bonded to each other;
11 is a perspective view taken along the AA portion of FIG.

The technical solutions of the present invention will be described in conjunction with the following drawings and examples.

Figure 4 is a perspective view of the expansion pipe of the present invention, Figure 5 is an exploded perspective view of the locking device of the expansion pipe of the present invention, Figures 6a and 6b is a perspective view showing the linkage of each component of the expansion pipe of the present invention, Figure 7 An axial partial cross-sectional view showing the linkage of each component in the locked state of the expansion pipe of the present invention, Figures 8a and 8b is a perspective view of the inner pipe of the expansion pipe of the present invention, Figure 9 is a base and inner in the locking device of the present invention 10 is a longitudinal cross-sectional view showing a pipe coupling state, FIG. 10 is a vertical cross-sectional view showing a support pipe and an inner pipe coupling state, and FIG. 11 is a cut-away perspective view of the AA portion of FIG. 9.

As shown in FIG. 4, the present invention stretch pipe includes an inner pipe 1, an out pipe 2, and a locking device 3, among which the inner pipe 1 is an out pipe 2. Slidably coupled within the interior, the locking device 3 is disposed at one end of the outer pipe (2). The outer contour of the locking device 3 is an arc structure surrounding the outpipe 2.

Figure 5 is an exploded perspective view of the locking device of the expansion pipe of the present invention. As shown, an expansion pipe 20 is provided at one end of the outpipe 2 of the expansion pipe of the present invention, and a mounting groove 201 is formed on the expansion pipe 20, and the base 7 to be described below is described. A portion (abbreviated as a lower projection) projects from the mounting groove 201 to the outside from the inside, and thus is fixed with the sliding cover plate 4 to be described below. In addition, a hook of the support 9 to be described below is fitted to one end of the mounting groove 201. Therefore, the movement of the support body 9 before and after and rotation of the right and left are restricted. By limiting the left and right relative rotation of the support 9 with respect to the outpipe 2 through this simple coupling structure, the inner pipe 1 movably coupled to the support 9 in the axial direction also has the outpipe ( The suppression of the left and right relative rotation for 2) can be ensured.

In addition, by reducing the bracket structure that is combined with the protrusion of the base that is commonly provided, the assembly and calibration process is omitted, and at the same time by reducing the parts, the mutual influence between the parts is reduced.

In addition, the locking device 3 of the flexible pipe of the present invention comprises a sliding cover plate 4 and a base 7, wherein the sliding cover plate 4 is the base 7 through the sliding hook 42. It is mounted on the upper surface of the cover and at the same time covers the entire upper surface, and proceeds the sliding movement in the axial direction under the stable guide action of the base (7).

The locking device 3 also comprises a spring 5 and a braking block 8. The spring 5 is one independent spring and is installed to correspond to the sliding direction of the sliding cover plate 4. The braking block 8 vertically moves along the driving hole 74 formed by penetrating vertically on the base 7. Only one spring 5 and one brake block 8 are accommodated between the sliding cover plate 4 and the base 7.

6A and 6B are perspective views illustrating the coupling relationship between the components of the present invention flexible pipe lock. As shown, the sliding cover plate 4 includes a gripping surface 41 and a sliding hook 42 provided on the bottom of the gripping surface 41, and through the sliding hook 42, on the base 7 to be described later. Are coupled to each other, causing the sliding cover plate 4 to slide relative to the base 7 in the axial direction.

In addition, the sliding cover plate 4 further includes a drive rod 44 installed on the bottom surface of the gripping surface 41. The driving rod 44 drives the braking block 8 to be described later, which causes the braking block 8 to lock or unlock the movement between the inner pipe 1 and the out pipe 2. The driving rod 44 has a braking surface 44 'and a driving surface 44 ", and the braking surface 44' and the driving surface 44" are braking surfaces 81 of the braking block 8 and It operates in conjunction with the driving surface 82.

That is, as shown in Figure 6b, the inclined surface, that is, the driving surface 44 "is formed at the end of the plurality of drive rods 44 formed extending vertically downward on the bottom of the gripping surface 41, the inclined surface is It is an arc-shaped slope.

The inclination angle of the arc-shaped inclined surface is 30 degrees to 45 degrees.

In addition, the sliding cover plate 4 further includes a spring driving groove 43. The spring driving groove 43 is provided on the bottom surface of the gripping surface 41 to seat the spring 5 therein, and to allow the sliding cover plate 4 to slide relative to the base 7. At this time, it causes the action of the driving member to cause the spring 5 to generate an elastic compression deformation.

In addition, one end of the spring driving groove 43 is further provided with a spring fixing rod (43 ') to prevent the spring (5) is pre-mounted and dropped when assembling mounting, it is possible to increase the assembly efficiency during assembly mounting Can be.

In addition, the gripping surface 41 is formed with a concave portion, the concave portion is installed to be combined with both the left and right muscle groups of the palm, so as to feel comfortable when the operator pulls, reducing the fatigue during use.

As shown, the base 7 includes a braking protrusion 71, a guide hook 72, a spring seating groove 73, a driving hole 74, and a support wing 75. The braking protrusions 71 are installed on the bottom surface of the base, and are installed symmetrically with respect to the center axis of the outpipe 2 as the axis of symmetry. The braking protrusion 71 is a braking inner surface 71 ″ coupled to the braking bottom surface 71 ′ in contact with the horizontal guide surface 14 of the inner pipe 1 and the braking inclined surface 12 of the inner pipe 1. The guide hanger 72 is a long rod-type track structure installed on the base upper surface and installed symmetrically with respect to the center of the outpipe 2 symmetrical axis, so that the sliding cover plate 4 is interlocked and covered. , Causes the sliding cover plate 4 to horizontally slide along the guide hanger 72. The spring seating groove 73 is provided at one end of the upper surface of the base to correspond to the spring driving groove 43 of the sliding cover plate 4. The driving hole 74 is installed at approximately the intermediate position of the base 7, and is installed to penetrate the entire base from the top to the bottom of the support blade 75 at the bottom of the base 7 back and forth. They are formed symmetrically in pairs and elongate.

In this way, the braking protrusion 71 provided on the base 7 engages with the inner pipe 1 at one end of the bottom of the base 7 so that the inner pipe 1 realizes movement guidance in the out pipe 2. At the same time, the inner pipe 1 realizes the effect of preventing torsional rotation in the outpipe 2. It will be described in detail in conjunction with Figure 9 below.

In addition, as described above, the base 7 protrudes from the mounting groove 201 formed on the expansion pipe 20 at one end of the outpipe 2 to protrude from the inside to the outside and is installed on the outpipe 2. do. At this time, the pair of support wings 75 formed to be symmetrically elongated at the bottom of the base 7 is in close contact with the inner wall of the outpipe 2, the expansion pipe 20, and a guide formed on the protruding portion of the base. Through the hook 72, it is coupled with the sliding hook 42 formed on the sliding cover plate 4, so that the entire locking device 3 is tightly engaged, and is firmly fixed on the outpipe 2 . Among them, the guide hanger 72 is optimally formed to form a long pair symmetrically back and forth.

In addition, as shown in the figure, inclined surfaces are formed at both ends of the bottom surface of the brake block 8, and the two inclined surfaces are symmetric with each other. In addition, the inclined surface is formed on the upper surface, but is formed only in part. That is, it is formed symmetrically back and forth about the middle horizontal plane. The inclined surface formed on the upper surface constitutes the driving surface 82 of the braking block 8, and the horizontal plane between the two front and rear pairs of the driving surface 82 constitutes the braking surface 81 of the braking block 8. do. The driving surface 82 and the braking surface 81 are each inclined plane formed on the driving rod 44 of the sliding cover plate 4, that is, a horizontal plane formed between the driving plane 44 ″ and the two inclined planes, that is, the braking plane ( 44 ') to lock and unlock movement between the inner and outpipes of the braking block 8.

As described above, the present invention enables the expansion pipe to be made stable and unobstructed in the operation process through the precise connection assembly relationship between the respective components, and also reduces unnecessary noise generated during the operation process. Therefore, the user's comfort and convenience during the use process is further improved. In addition, the assembly strength is ensured, while the structure is the simplest and the manufacturing cost is the lowest.

Hereinafter, the operation of locking and releasing the expansion pipe will be described with reference to FIG. 7.

As shown, the presently shown state is locked. At this time, if the operator applies a force to the sliding cover plate 4 in the direction of the hollow arrow (B) to the back, the sliding cover plate 4 is the spring seating groove 73 and the sliding cover plate 4 of the base (7) While overcoming the elastic pressure of the spring 5 seated in the spring driving groove 43 formed integrally with the bottom surface of the), it slides backward in the direction of the arrow B 'in the solid double arrow. At this time, the driving rod 44 integrally formed with the sliding cover plate 4 at an approximately intermediate position of the bottom portion thereof is moved back together. At this time, the state in which the braking surface 44 'of the driving rod 44 presses the braking surface 81 of the braking block 8 is released. Therefore, at this time, the operator is inner against the outpipe 2. When the pipe 1 is pulled or inserted, the braking block 8 moves up and down without obstacles along the driving hole 74 of the base 7. At this time, by the locking inclined surface 13 of the inner pipe locking projection 11 and the rounding treatment on the cross line side and the arc-shaped inclined surface formed at the end of the driving rod 44, that is, the driving surface 44 ", the braking block 8 is provided. This makes it possible to move up and down much smoother and more stably under the driving and guiding of the inclined surface, thus reducing the vibration and noise caused by the coupling between the brake block 8 and other components.

When the operator releases the sliding cover plate 4 after completing the extension or contraction of the stretching pipe contraction, the sliding cover plate 4 moves to the arrow A in the solid double arrow according to the action of the elastic recovery force of the spring 5. ') And forward, in this case, the driving rod 44 formed at the approximately intermediate position of the lower portion integrally with the sliding cover plate 4 is moved forward together, at this time, The driving surface 44 "operates in conjunction with the driving surface 82 of the braking block 8, gradually presses the braking block 8 downward, thereby braking surface 44 'of the final driving rod 44. It is pressed and covered on the braking surface 81 of the braking block 8. Therefore, at this time, the bottom surface of the braking block 8 is formed between two locking projections 11 provided on the inner pipe 1. It is inserted into the locking groove to cause the inner pipe 1 to stop relative movement with respect to the out pipe 2.

On the contrary, when the operator exerts a forward force on the sliding cover plate 4 in the direction of the hollow arrow A, the sliding cover plate is a spring formed integrally with the spring seating groove 73 of the base 7 and the bottom of the sliding cover plate. While overcoming the elastic pressure of the spring 5 seated in the drive groove 43, it slides forward in the direction of the arrow A 'of the solid double arrow. At this time, the driving rod 44 integrally formed with the sliding cover plate 4 at an approximately intermediate position of its bottom portion moves forward together. At this time, the pressing state of the braking surface 81 of the braking block 8 of the braking surface 44 'of the driving rod 44 is released. Therefore, at this time, when the operator pulls or inserts the inner pipe 1 relative to the out pipe 2, the braking block 8 moves up and down without obstacle along the driving hole 74 on the base 7. do. At this time, the braking block is caused by the locking inclined surface 13 of the inner pipe locking projection 11 and the rounded round processing on the cross line and the arc-shaped inclined surface formed at the end of the driving rod 44, that is, the driving surface 44 ". Under the driving and guiding of the inclined surface, it moves up and down much smoother and more stably, thus reducing the vibration and noise caused by the coupling between the brake block 8 and other components.

Similarly, when the operator releases the sliding cover plate 4 after completing the operation of the expansion or contraction expansion pipe, under the action of the elastic recovery force of the spring 5, the sliding cover plate 4 is an arrow in the solid double arrow. Sliding backward in the direction of (B '), at this time, the driving rod 44 formed at an approximately intermediate position of the lower portion integrally with the sliding cover plate 4 is moved back together, the driving rod 44 Driving surface 44 " of the brake block 8 operates in conjunction with the driving surface 82 of the braking block 8 to gradually press the braking block 8 downwards, so that the braking surface 44 of the final driving rod 44 ') Is pressed on the braking surface 81 of the braking block 8. Thus, the bottom of the braking block 8 causes the bottom of the braking block 8 to be interposed between the two locking projections 11 installed on the inner pipe 1. It is inserted into the formed locking groove to cause the inner pipe 1 to stop the relative movement with respect to the out pipe 2. All.

The spring 5 is horizontally installed in the spring seating groove 73 and the spring driving groove 43.

In addition, both side walls of the spring driving groove 43 integrally formed at the bottom of the sliding cover plate 4 limit the left and right positions of the spring 5 and at the same time, the sliding cover plate 4 can operate. At this time, the spring is caused to have a function of generating a driving force by compression deformation.

In addition, the spring 5 acts in a compressed state all the time, and does not act while deforming alternately in the stretched and compressed states. Therefore, the life of the spring can be extended. At the same time, the spring 5 is compressed by receiving the action force alternately in the left and right ends. Therefore, the service life can be significantly extended compared to the spring in which one end is fixed and the other end is repeatedly applied.

As the spring 5 as described above is guaranteed its reliability, it is possible to further ensure the operation reliability of the entire locking device.

Further, not only the automatic recovery of the original state of the sliding cover plate is realized by the one spring, but also the locking state maintenance function of the locking device is realized.

8 to 11, the torsional rotation preventing structure of the flexible pipe of the present invention will be described.

First, the structure of the inner pipe 1 of the present invention will be described with reference to FIG. 8 so as to describe the expansion pipe torsion preventing structure of the present invention in more detail. On one end circumferential surface of the tubular surface of the inner pipe 1, a locking surface 10 is formed horizontally along the central axis direction, and a plurality of lock surfaces 10 are spaced apart at regular intervals along the central axis direction. Four locking protrusions 11 are formed to protrude upward, the locking protrusion 11 is formed with four sides and one horizontal upper surface circumferentially, of which each side between the two locking projections 11 is locked It constitutes an inclined surface 13, and also between the two locking projections constitute a locking groove, and the other two side surfaces of the locking projection 11 constitute a braking slope 12, respectively. On the locking surface 10, adjacent to the locking projection 11, a guide surface 14 is formed along the center axial direction, among which the braking slope 12 and the guide surface 14 are the locking device 3. ), The inner pipe 1 serves to prevent the torsional rotation on the circumferential direction inside the outpipe 2 and to guide the inner pipe 1.

In addition, the intermediate side is inclined inwardly from the bottom to the upper end, and each side of the locking projection 11 is a rounding process of all the intersection line with the locking surface 10 and the upper surface of the locking projection 11, When combined with the brake protrusion 71 and the brake block 8, it is possible to operate more smoothly and stably.

Therefore, the inner pipe 1 causes the locking and unlocking action of the inner pipe 1 in the outpipe 2 due to the combination of the structure of the braking slope 12 of the guide surface 14 and the locking protrusion 10 and the locking device. In addition, by causing the action of the torsion preventing groove separately installed in the prior art, to enhance the identity of the entire inner pipe, thereby improving the airtightness when the inner pipe (1) operates in the outpipe (2), In the process of user use, while the inner pipe 1 is in an extended state, it is possible to reduce the use interference formed by installing a torsion prevention groove in addition to the locking surface of the locking projection, thereby further increasing user convenience and comfort. In addition, when viewed from the outside, the inner pipe is a flat gloss surface, and thus brings a visually perfect aesthetic during the user's use process. And enhance a sense of enemy.

As shown in FIG. 6, the pair of braking protrusions 71 formed at one end of the bottom surface of the base 7 respectively has a braking bottom surface 71 'and a braking inner side surface (generally perpendicular to the braking bottom surface 71'). 71 ''); Among them, the braking inner surfaces 71 ″ of the pair of braking protrusions 71 abut against each other.

FIG. 10 shows a cross-sectional view of the coupling state of the base 7 and the inner pipe 1 of the locking device 3. As shown, the braking bottom 71 'and the braking inner surface 71' 'of the braking protrusion 71 are guide surfaces 14 and braking inclined surfaces 12 of the locking surface 10 of the inner pipe 1, respectively. In close contact with the braking projection 71, the braking inclined surface 12 'of the braking projection 71 is in close contact with the guide surface 14 of the locking pipe 10 of the inner pipe 1, and the inclined braking surface 12 of the locking projection 11 ) Prevents the braking inner surface 71 '' of the braking protrusion 71, and thus prevents the braking inner surface 71 '' from crossing the locking projection 11, thereby preventing the At the same time, the braking protrusion 71 also engages with the guide surface 14 of the locking pipe 10 of the inner pipe 1 so that the inner pipe 1 has an outpipe ( 2) It causes the action of guiding the movement stably within.

On the other hand, as shown in Fig. 5, the support 9 has a cylindrical structure, one end of the support 9 is inserted from the outpipe 2 expansion tube 20, and the other end is formed on the circumferential surface thereof. It hangs on the mounting groove 201 formed on the expansion pipe 20 of the outpipe 2 via the hook 92, and thus causes a supporting action. The length of the support 9 corresponds to the length of the expansion pipe 20, thereby ensuring the action according to the support strength of the support 9. In addition, an opening groove 93 is cut in one end of the circumferential surface of the support 9 so as to correspond to the mounting groove 201 of the expansion pipe 20, and the opening groove 93 is the outpipe 2 and the expansion pipe 20. It is formed slightly larger than the upper mounting groove 201, so that the support blade 75 of the locking device (3) base 7 can be matched, thereby causing the action of supporting the locking device (3).

On the inner circumferential surface of the support body 9, a pair of braking protrusions 91 are provided symmetrically with respect to the outpipe center axis so as to correspond to the position of the mounting groove 201 of the expansion pipe 20. A braking inner surface 91 '' is formed on the bottom surface 91 'and at a right angle to the braking bottom surface 91'.

In addition, the pair of braking protrusions 91 of the support body 9 and the pair of braking protrusions 71 of the base 7 are located on the same straight line in the central axis direction of the expansion pipe.

In addition, a plurality of reinforcing ribs 94 are provided on the inner circumferential surface of the support body 9 to increase the strength of the support body 9, and when the inner pipe 1 slides therein, the inner pipe ( There is an effect of guiding the stable movement of 1).

10 is a cross-sectional view showing a state in which the support and the inner pipe are coupled, and FIG. 11 is a cross-sectional view taken along the line A-A of FIG. As shown, the braking bottom surface 91 'and the braking inner surface 91' 'of the braking protrusion 91 are guide surfaces 14 and braking slopes 12 of the inner pipe 1 locking surface 10, respectively. In close contact with the braking protrusion 91, the braking inclined surface 91 'of the braking protrusion 91 is in close contact with the guide surface 12 of the locking pipe 10 of the inner pipe 1. 12 prevents the braking inner surface 91 '' of the braking protrusion 91, thereby preventing the braking inner surface 91 '' from crossing the locking projection 11, thereby making the inner pipe 1 The braking protrusion 91 is also engaged with the guide surface 14 of the locking surface 10 of the inner pipe 1 and at the same time the inner pipe 1 is outpiped. (2) Produces the action of guiding stable movement within.

As described above, the present invention stretch pipes slightly extend the locking surface of the inner pipe locking projections existing in the prior art in the circumferential diameter direction to form a guide surface, and then use the locking projections finely coupled to the prior art. By realizing the function of the torsion prevention mechanism which already exists, i.e., by providing the torsion preventing groove separately on the opposite side on the base of the locking projection locking surface, the airtightness of the duct and the airflow flow flow rate are improved. It is possible to realize the anti-twist function without the need for an increase of, thereby effectively increasing the production efficiency.

1: inner pipe 10: locking surface
11: locking protrusion 12: braking slope
13: locking slope 14: guide surface
2: Outpipe 20: Expansion
201: mounting groove 3: locking device
4: sliding cover plate 41: gripping surface
42: sliding hook 43: spring driving groove
43 ' : Spring fixing rod 44: Driving rod
44 ': Braking surface 44 ": Chugging surface
5: spring 7: base
72: guide hanger 73: spring seating groove
74: driving hole 75: support wing
8: braking block 81: braking surface
82: driving surface 9: support
71, 91: Braking bumps 71 ', 91': Braking bottom
71 '', 91 ': Braking inner side 92: Hanger
93: opening groove 94: reinforcing rib

Claims (2)

An inner pipe (1), an outpipe (2), and a locking device (3), the inner pipe (1) being slidably connected in the outpipe (2), In the expansion pipe which is equipped with the locking device (3) at one end,
The locking device 3,
A sliding cover plate 4;
Base 7;
A spring (5) installed in a space formed between the sliding cover plate (4) and the base (7); And
And a braking block 8 vertically moving up and down in the driving hole 74 installed on the base 7.
The upper end of the base 7 protrudes upward through the mounting groove 201 formed at one end of the outpipe 2 from the inside to the outside,
Guide hooks 72 are installed on the upper surface of the base 7 so that the center axis of the outpipe 2 is symmetrically back and forth, and sliding hooks 42 are provided on the bottom surface of the sliding cover plate 4. When the sliding hook 42 of the sliding cover plate 4 is moved horizontally along the guide hook 72 formed on the upper surface of the base 7, the sliding cover plate 4 is connected to the base 7. Relative motion sliding in the axial direction with respect to
The sliding cover plate 4 covers an upper end of the base 7, and is configured to surround an area corresponding to the base 7 on the outer contour of the outpipe 2,
The sliding cover plate 4 further includes a driving rod 44 provided on the bottom surface of the gripping surface 41, and the driving rod 44 is disposed between the driving surface 44 ″ and the inclined surface by an inclined surface of the distal end. The braking surface 44 'is provided by a horizontal plane formed so that the braking surface 44' operates in combination with the braking surface 81 of the braking block 8, and the braking surface 44 " The braking block 8 is configured to operate in conjunction with the driving surface 82, wherein the braking block 8 has an inclined surface formed before and after the upper surface to form the driving surface 82, the horizontal plane between the inclined surface is Stretch pipes, characterized in that to form a copper surface (81). An inner pipe (1), an outpipe (2), and a locking device (3), the inner pipe (1) being slidably connected in the outpipe (2), In the expansion pipe which is equipped with the locking device (3) at one end,
The locking device 3,
A sliding cover plate 4;
Base 7;
A spring (5) installed in a space formed between the sliding cover plate (4) and the base (7); And
And a braking block 8 vertically moving up and down in the driving hole 74 installed on the base 7.
The base 7 is,
A driving hole 74 formed at the center of the braking block 8 so as to vertically move vertically;
A pair of guide hooks 72 formed on both sides of the driving hole 74 to guide the sliding hooks 42 formed on the bottom surface of the sliding cover plate 4 to move along the axial direction;
A spring seating groove 73 formed at one side of the driving hole 74 to allow the spring 5 to be seated thereon; And,
And a pair of support wings 75 formed on both sides of the driving hole 74 symmetrically in front and back to be in contact with the inner wall of the outpipe 2. Protrudes upward through the mounting groove 201 formed at one end of the outpipe (2) from the inside to the outside,
The sliding cover plate (4) covers the upper end of the base (7), the expansion pipe, characterized in that configured to surround the area corresponding to the base (7) on the outer contour of the outpipe (2).

Images