KR101543240B1 - Vacuum fixer of rail type - Google Patents

Abstract

The present invention relates to a rail type vacuum absorber and, more specifically, to a rail type vacuum absorber having a two-piece structure including: an absorbing plate wherein a screw rod is installed at the upper center and a hard rotary rail is installed at the upper outer edge; and a rotary cap wherein a screw pipe for insertion of the screw rod is formed at the inner center and a sliding rim corresponding to the rotary rail is formed around the edge.

Description

[0001] Vacuum fixer of rail type [0002]

[0001] The present invention relates to a rail-type vacuum adsorbent, more particularly, to a rail-type vacuum adsorbing apparatus which comprises a suction plate provided with a screw rod at the center of its upper surface and a hard- And a rotary cap having a sliding rim corresponding to the rotary rail at a rim of the rail type vacuum suction port.

Vacuum adsorbent is a household product that is constructed to easily attach a towel rack or soap bar to a mirror or a tile wall by using a soft absorbent plate such as an octopus sucker. It can easily change the attachment position if necessary, It is convenient. Conventionally, vacuum adsorption structures having various structures have been developed. Depending on the number of major components involved before the adsorption force generator, one-piece type, two-piece type, and three-piece type have.

First, the one-piece type vacuum adsorption unit is composed of only an elastic adsorption plate having a recessed concave bottom surface, and adsorption force is generated by the shape restoring force of the adsorption plate itself. Such a one-piece type is advantageous in that it is simple in structure, low in manufacturing cost, and easy to use, but has a disadvantage that its application is limited because of its weak adsorption power.

Thus, in Korean Patent Laid-Open No. 10-2010-0060054 (Jun. 2010), a spring is installed in the center of the adsorption plate to improve the restitution force of the one-piece adsorption plate. Korean Patent Laid-Open No. 10-2004-0034108 (Apr. 24, 2004) discloses a vacuum adsorption apparatus in which an O-ring is inserted into the upper edge of the adsorption plate and an elastic cover plate is provided thereon. The O-ring disperses the load applied to the adsorption plate to prevent the adsorption endurance from being lowered, and the cover plate functions to improve the restoring force of the adsorption plate.

Next, the three-piece type vacuum adsorption device comprises a suction plate 10, a pressing cap 20, and a tightening device 30, as shown in FIG. The attracting plate 10 is soft and has a threaded rod 11 on its upper surface, and a flat bottom surface is brought into close contact with the adhered surface S. The pushing cap 20 covers the adsorption plate 10, and the screw rod 11 passes through the center. The tightening tool 30 is installed on the screw rod 11 protruded above the pushing cap 20 and pulls the screw rod 11. In FIG. 1, the tightening tool 30 is illustrated as a screw for the sake of convenience. However, the tightening tool 30 may be a lever type using a lever principle.

When the screw rod 11 is lifted using the tightening tool 30 in a state in which the bottom surface of the adsorption plate 10 is in close contact with the surface S to be adhered to the adsorption plate 10, (Hereinafter, referred to as a vacuum chamber C) is formed between the surface S and an adsorption port is attached to the adherend surface by the vacuum force of the vacuum chamber C. At this time, the adsorption strength of the vacuum adsorption port is proportional to the volume of the vacuum chamber (C), and the adsorption endurance is proportional to the airtightness of the vacuum chamber (C).

In this way, in the three-piece vacuum adsorption tool, the threaded rod 11 is forcibly lifted to enlarge the volume of the vacuum chamber C. In this process, the rim of the adsorption plate 10 pulls up toward the center, 10 and the adherend surface S is disturbed, and this phenomenon ultimately causes the airtightness of the vacuum chamber C to be weakened.

To solve this problem, the applicant of the present invention has proposed a vacuum adsorber having a gel-type polyurethane vacuum wall on the bottom surface of a press plate in International Publication WO2005-35999 (Apr. 21, 2005). The adsorption orifice maintains excellent adsorption endurance because the sticky vacuum wall covers the rim of the adsorption plate and improves the airtightness of the vacuum chamber (C).

Japanese Utility Model Registration No. 3014841 (Jun. 7, 1995) discloses a vacuum adsorption device in which an adhesive material is adhered to the bottom edge or entire surface of the adsorption plate. The viscous material improves the airtightness of the vacuum chamber (C) and functions to provide a physical adhesion force between the adsorption plate and the adherend.

On the other hand, a two-piece type vacuum adsorption unit made up of a cap (1) and a suction plate (5) is disclosed in the Korean Registered Utility Model No. 20-0233533 (May 28, 2001) The suction plate 5 is provided with a male screw portion 7 and the cap 1 is provided with a pressing step 2 for pressing and holding the edge of the suction plate 5, (Not shown). Thus, when the cap 1 is rotated, the male screw part 7 rises into the female screw part 3, and a vacuum chamber is formed on the bottom surface of the attracting plate 5. Below the cap 1, there is provided a ring 4 for hanging another object.

Korean Patent Publication No. 10-2010-0060054 (2010.06.07.) Korean Patent Publication No. 10-2004-0034108 (April 28, 2004) Korean Registered Utility Model No. 20-0233533 (May 28, 2001) International Publication WO2005-35999 (Apr. 21, 2005) Japanese Utility Model Registration No. 3014841 (June, 1995)

The two-piece vacuum adsorbent as shown in FIG. 2 has a structure that is simpler in structure than the three-piece type because the cap 1 also serves as the push-up cap 20 and the tightening member 30 of the three- There is an advantage of low cost. However, in order to increase the volume of the vacuum chamber C, the male screw portion 7 must be lifted forcibly as in the case of the three-piece type. In this process, the edge portion of the suction plate 5 is pulled up along the male screw portion 7 The airtightness of the vacuum chamber C is lowered.

In addition, since the pressing step 2 of the cap 1 is engaged with the edge line of the suction plate 5, the cap 1 can not sufficiently adhere the suction plate 5 to the adherend surface S, There is a problem that the rim portion of the movable member 5 is pulled up toward the center and is released from the pushing step 2.

When the cap 1 is rotated to lift the male threaded portion 7, the pressing step 2 of the cap 1 is rotated in contact with the suction plate 5. At this time, the suction plate 5 Is functionally soft, the frictional force is high, which interferes with the rotation of the cap 1. [ Therefore, when the cap 1 rotates, the attracting plate 5 also slightly rotates, which also causes disturbance of the adhered state between the attracting surface and the attracting plate 10.

As described above, the conventional two-piece type vacuum adsorbent has a structure which is simple compared to the three-piece structure, but has a problem that the adsorbing force is significantly lowered. It is an object of the present invention to solve such a technical problem.

A rail-type vacuum adsorbing apparatus according to the present invention comprises: a flexible adsorption plate provided with a screw rod at the center of an upper surface thereof and a rigid rotating rail provided in a circumferential direction at an outer surface of the upper surface; And a rigid rotating cap covering a top surface of the attracting plate and having a screw hole for inserting the screw rod therein and a sliding rim corresponding to the rotating rail at a rim ; And a circular sliding surface formed in a single plane extending in a horizontal direction on a circumference centered on the screw rod is developed in the rotary rail.

Therefore, when the rotating cap is rotated, the bottom surface of the sliding rim slides along the sliding surface, and the screw rod is raised into the screw hole.

Since the rail type vacuum adsorber according to the present invention has a two-piece structure of a suction plate and a rotary cap, the structure is simpler than that of the conventional three-piece type and the manufacturing cost can be reduced.

In addition, since the rail type vacuum adsorber according to the present invention reduces the frictional force between the attracting plate and the rotary cap, the deformation of the attracting plate is prevented and the load applied to the attracting plate is dispersed. Therefore, There is an effect that the adsorption strength and the adsorption endurance are further improved.

Further, since the rail-type vacuum adsorbent according to the present invention does not have a configuration corresponding to the three-piece throttle structure, the structure of the rotary cap can be variously changed, and in particular, It is effective.

FIG. 1 is a view showing a structure of a conventional three-piece vacuum suction port,
FIG. 2 is a view showing an example of a conventional two-piece vacuum suction device,
FIG. 3 is an exploded perspective view of a rail-type vacuum adsorption device according to the present invention,
Fig. 4 is an exploded sectional view of Fig. 2,
Figure 5 is an assembled cross-sectional view of Figure 2,
6 shows an example of use of a rail-type vacuum adsorption device according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, in FIGS. 3 to 6 illustrating the present invention, each component is given its own name and reference numerals regardless of FIG. 1 and FIG. It should be noted that the scope of protection of the present invention is not limited by these embodiments, as the embodiments of the present invention have been described with reference to the accompanying drawings.

3 and 4, the rail-type vacuum adsorbing unit according to the present invention comprises a suction plate 10 and a rotary cap 20. As shown in FIG.

First, the adsorption plate 10 is made of a stretchable soft material, and the bottom surface in close contact with the adhered surface has a flat structure. A screw rod 11 is installed vertically at the center of the upper surface of the attracting plate 10 and a rotary rail 12 is provided at a periphery of the upper surface in a circumferential direction.

The rotary rail 12 is made of a rigid hard material and has at least one sliding surface 12a spread on a circumference centered on the threaded rod 11. [ The material of the rotary rail 12 is preferably a metal or a hard synthetic resin. The sliding surface 12a may have any structure as long as it is slidable, but it is preferable that the sliding surface 12a is formed in one plane that extends in the horizontal direction. However, the sliding surface 12a may have an inclined surface or a curved surface in cross section.

4, the rotating rail 12 may be attached to the upper surface of the attracting plate 10. However, when the attracting plate 10 is molded, an insert is formed with the screw rod 11 to form the exciting plate 12, It is preferable that the lower part of the suction plate 10 is buried in the suction plate 10. However, in any case, the sliding surface 12a must be exposed above the adsorption plate 10. [

An adhesive layer may be applied to a part or the entire surface of the bottom of the adsorption plate 10. The adhesive layer is made of, for example, a sticky polyurethane material, and functions to enhance the attraction force between the adsorption plate 10 and the adherend.

Next, the rotary cap 20 covers the upper surface of the adsorption plate 10 and is made of a hard and hard material. The rotary rail 12 and the rotary cap 20 may be made of the same material or may be made of different materials, but it is preferable to select a material having a low frictional force.

The rotary cap 20 is formed at its inner center with a screw pipe 21 into which the screw rod 11 is inserted and a sliding rim 22 corresponding to the rotary rail 12 is provided at a rim . When the rotary cap 20 is covered with the bottom surface of the suction plate 10 in close contact with the adhered surface of the suction plate 10, the threaded rod 11 corresponds to the threaded tube 21, And corresponds to the sliding rim 22.

When the rotary cap 20 is rotated in this state, the bottom surface 22a of the sliding rim 22 slides along the sliding surface 12a of the rotary rail 12, So that it ascends into the screw tube 21. [ A vacuum chamber C is formed between the bottom surface of the adsorption plate 10 and the adhered surface while the central portion of the adsorption plate 10 is forcibly lifted along the screw rod 11.

According to an embodiment of the present invention, the sliding surface 12a is formed in one plane extending in the horizontal direction, and one of the contour line or the outline of the sliding surface 12a is provided with And a guide wall 12b slidably contacting one of the inner circumferential surface and the outer circumferential surface. 4 and 5 show a structure in which a guide wall 12b is formed along the contour line of the sliding surface 12a and the guide wall 12b is in contact with the inner peripheral surface of the sliding rim 22 . The guide wall 12b functions to guide the bottom surface 22a of the sliding rim 22 so as not to move away from the sliding surface 12b when the rotary cap 20 rotates.

The rotation rail 12, which is a feature of the present invention, facilitates the rotation of the sliding rim 22 to help smoothly raise the screw rod 11. When the threaded rod 11 is lifted up, the edge of the suction plate 10 is supported to prevent deformation of the suction plate 10, thereby improving the airtightness of the vacuum chamber C as a result.

Also, the rotating rail 12 functions to improve the endurance of the adsorption by dispersing the load applied to the adsorption plate 10. In general, the vacuum adsorption plate is attached on the adherend surface S arranged in the vertical direction, and is used mainly for hanging a household article such as a soap bar on the vacuum adsorption plate. Therefore, most of the attracting plate 10 receives a load in the gravity direction, and when the attracting plate 10 is dropped on the placing surface S, the attracting plate 10 is mostly fallen from the top. This unidirectional load eventually causes a decrease in the adsorption endurance of the vacuum adsorption orifice.

However, in the present invention, the rotating rail 12 supports the edge of the adsorption plate 10 to disperse the one-directional load applied to the adsorption plate 10 to the entire adsorption plate 10, and as a result, the adsorption endurance is improved will be.

5, since the width of the rotary rail 12 is wider than the thickness of the sliding rim 22, the area of the rim of the suction plate 10 is pressed against the adherend surface S, The result contributes to improving the airtightness of the vacuum chamber (C).

In the present invention, a first stopper is provided on the upper surface of the attracting plate 10, and a second stopper (not shown), which is coupled to the first stopper and restricts rotation of the rotation cap 20, Can be installed. The stopper functions to allow the user to recognize that the vacuum chamber C having a sufficient size is secured in the attraction plate 10. Therefore, when the vacuum suction port is attached to the adherend surface S, it is convenient to use the rotary cap 20 only when the first stopper and the second stopper are engaged.

In addition, the stopper functions to stop the rotation angle of the rotary cap 20 at a constant position. 3 to 5 of the present invention, no components are added to the rotary cap 20 for the sake of convenience. However, considering the use of the vacuum suction port, the rotary cap 20 may have a hook, a handle, And a case ground. FIG. 6 is a view illustrating a structure in which a towel bar H is mounted on the upper surface of the rotary cap 20a according to an embodiment of the present invention. Therefore, it is very useful that the rotation cap 20a stops at a certain angle when the attraction plate 10 has a sufficient attraction force.

The structure of the stopper may be any structure as long as it can achieve the object of the present invention. 3, the first stopper is a rectangular protrusion 13 protruding around the threaded rod 11, and the second stopper is protruded around the threaded tube 21, And a rectangular tube 23 coupled to the square protrusion 13. The square protrusion 13 and the square tube 23 may have a pentagonal or hexagonal structure.

Finally, since the rail-type vacuum adsorption device according to the present invention does not have a configuration corresponding to the three-piece type fastening port, the outer shape and structure of the rotary cap 20 can be variously changed. For example, the outer shape of the rotary cap 20 can be variously configured as a square, a star, a heart, an animal hair shape, a flower shape, and the like. In particular, a vacuum adsorption structure having a flat structure with a low height can be manufactured. The ability to variously change the outer shape and structure of the rotary cap 20 means that the application range of the vacuum suction port can be expanded according to various demands of consumers.

10; Attracting plate 11; Na Sa Bong
12; A rotating rail 12a; Sliding surface
12b; Guide wall 13; Square projection
20,20a; A rotating cap 21; Screwman
22,22a; Sliding rim 23; Square tube
C; Vacuum chamber H; Towel rack
S; Adhered face

Claims (6)

And a sliding rim 22 which is in close contact with an edge of the upper surface of the attracting plate 10, a screw 21 which is inserted into the screw rod 11, And a hard rotatable cap (20) having a bottom surface and a bottom surface;
On the upper surface of the attracting plate 10, a hard rotating rail 12 is provided in a circumferential direction at a portion contacting the bottom surface 22a of the sliding rim 22,
On the upper surface of the rotary rail 12, a circular sliding surface 12a formed in a plane extending in the horizontal direction on a circumference centered on the threaded rod 11 is provided, and the circular sliding surface 12a of the sliding surface 12a And the lower portion is buried in the adsorption plate (10).
The method according to claim 1,
Characterized in that a part or the whole of the bottom surface of the adsorption plate (10) is coated with an adhesive layer.
delete 3. The method according to claim 1 or 2,
Characterized in that a guide wall (12b) slidable in contact with any one of an inner circumferential surface and an outer circumferential surface of the sliding rim (22) is provided on either of an inner circumferential line or an outer circumferential line of the sliding surface (12a) Adsorption sphere.
3. The method according to claim 1 or 2,
A first stopper is provided on the upper surface of the attracting plate 10 and a second stopper coupled to the first stopper is provided in the rotation cap 20 to restrict rotation of the rotation cap 20 Features a rail-type vacuum adsorber.
6. The method of claim 5,
The first stopper is a rectangular protrusion 13 protruding around the threaded bar 11. The second stopper protrudes around the threaded pipe 21 and has a lower end connected to the rectangular protrusion 13, (23). ≪ / RTI >

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