KR20070059289A - Vacuum fixer - Google Patents

Abstract

A vacuum absorbing tool is provided to reduce the space between an absorbing plate and a surface to be adhered and increase the area on which the absorbing plate and the surface to be adhered comes into contact with each other. The vacuum absorbing tool includes a soft absorbing plate(100) and a hard housing(200). The housing(200) covers the absorbing plate(100). The absorbing plate(100) includes a first inclination, two or more ventilation holes and a connection groove. The housing(200) includes a ceiling portion, a vacuum wall, an exhaust hole and a recess portion. The ceiling portion pushes an upper surface of the absorbing plate. In the recess portion of the housing(200), a one-direction exhaust valve stopping the exhaust hole and a finishing cap are installed.

Description

Vacuum adsorber {Vacuum fixer}

1 is a view showing the structure of a conventional vacuum suction port,

2 is a cross-sectional view of a vacuum suction port according to an embodiment of the present invention,

3 is an exploded cross-sectional view of a vacuum suction port according to an embodiment of the present invention;

4 is a plan view of the suction plate 100,

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a cross-sectional view of the housing 200.

<Description of Symbols for Main Parts of Drawings>

100; Adsorption plate 110; Upper surface

120; Bottom surface 130; First slope

140; Vent 150; Connecting groove

160; Step 200; housing

210; Ceiling 220; Vacuum wall

230; Second inclined surface 240; Vent

250; Recess 260; Step

270; Protective wall 300; One-way valve

400; Closing cap

The present invention relates to a vacuum suction port used to attach an object to an adhered surface by using an adsorption plate, and more specifically, to reduce the space between the adsorption plate and the adhered surface as much as possible, and instead, the area where the adsorption plate and the adhered surface contact. In particular, the present invention relates to a vacuum suction port configured to maintain an excellent adsorption force for a long time with respect to a load acting in a direction parallel to the surface to be deposited.

In general, in order to hang or fix an object on a tile wall or glass surface, which is difficult to use screws or nails, a vacuum suction hole using a suction plate of the same principle as a sucker attached to a leg such as octopus or octopus (also called 'cubang') ) Is used a lot. As such, the vacuum suction port has a generally plate-shaped suction plate, and the suction plate is placed on a smooth adherend such as glass or tile to remove the air inside the suction plate, and then the volume inside the suction plate is forcibly enlarged. That is, since the atmospheric pressure is much higher than the pressure inside the adsorption plate, and eventually the atmospheric pressure presses the adsorption plate, the adsorption port is attached to the adherend surface.

Conventionally, vacuum adsorption holes of various structures have been introduced. However, these conventional vacuum adsorption holes have a disadvantage that they do not adhere at all, or the adhesive force is not maintained for a long time because the adsorption plate does not maintain a perfect vacuum in the case of minute scratches or irregularities on the adhered surface. In order to solve this problem, the inventors of the Korean Registered Utility Model No. 397850 (registered on September 30, 2005) include a hat-shaped pressing plate 10 made of a hard synthetic resin, and a soft covering on the pressing plate 10. A disk-shaped suction plate 20 made of synthetic resin, and a screw shaft 30 installed at the upper center of the suction plate 20 and penetrating the center of the pressing plate 10 and coupled to the protruding end of the screw shaft 30. Consists of a fastener 40, the introduction of the suction port, characterized in that the gel-type polyurethane vacuum wall 11 protruding toward the adhered surface 80 is installed on the edge of the pressing plate 10. In the adsorption port of No. 397850, the vacuum wall 11 provided on the pressing plate 10 fills the scratches or irregularities of the adherend 80 even if there are some scratches or irregularities on the adhered surface 80 to maintain the vacuum state. Because of the cycle, there is an effect of maintaining a superior adhesion for a long time compared to the conventional adsorption port.

However, in order to maintain a predetermined adhesive force of the conventional adsorption holes, including the adsorption port of the Korean Utility Model No. 397850, as shown in FIG. 1, the space between the adsorption plate 20 and the deposition surface 80, that is, the portion A It is necessary to maintain a certain vacuum, in fact, it is practically impossible for part A to maintain the initial vacuum for months to years. After a predetermined time has elapsed after attaching the conventional adsorption port to the adhered surface, the adsorption plate 20 hardens, and air may gradually be smeared through the minute space between the adsorption plate 20 and the adhered surface 80, Air may smear little by little even through the structure of the 20 and the adherend 80 itself. For this reason, the adsorption power of the conventional adsorption port is significantly reduced after several weeks or one to two months. Furthermore, since the vacuum suction port is usually used to suspend other objects, a considerable load is applied in the direction parallel to the deposition surface 80, that is, the B direction. Therefore, the vacuum suction holes of the conventional structure had a structural limit that can be dropped from the surface to be deposited after a certain time.

The present invention was developed to overcome the limitations of the conventional vacuum suction port as described above, and the space between the adsorption plate and the adhered surface is reduced as much as possible, and instead, the area between the adsorption plate and the adhered surface is increased as much as possible. It is an object of the present invention to provide a vacuum suction port configured to maintain an excellent suction force for a long time with respect to a load acting in a parallel direction.

In order to achieve the above object, the vacuum suction port of the present invention comprises a soft suction plate adhered to the adhered surface, and a hard housing covering the suction plate; The suction plate is a plate body consisting of a top surface and a bottom surface as a first inclined surface formed along an outline, at least two air vents penetrating the bottom surface from the top surface, and a connection groove formed in the bottom surface such that the vent holes communicate with each other Configured; The housing is any one of a ceiling for pressing the upper surface of the suction plate, a vacuum wall having a second inclined surface formed in the periphery of the ceiling and contacting the first inclined surface of the suction plate, and through the ceiling of the suction plate. An exhaust hole communicating with the groove, and a recess formed outside the upper end of the exhaust hole; The groove portion of the housing is characterized in that the one-way exhaust valve blocking the exhaust hole, the closing cap is installed.

Hereinafter, the present invention according to the accompanying drawings in more detail as follows.

2 is a cross-sectional view of a vacuum suction port according to an embodiment of the present invention, Figure 3 is an exploded cross-sectional view of the vacuum suction port according to an embodiment of the present invention, Figure 4 is a plan view of the suction plate 100, Figure 5 is a view 4 is a cross-sectional view taken along line AA, and FIG. 6 is a cross-sectional view of the housing 200.

2 and 3, the vacuum suction port of the present invention is a soft suction plate 100 adhered to the adhered surface, a hard housing 200 covering the suction plate 100, and a one-way exhaust valve installed on the housing 200. It consists of a 300 and the closing cap (400).

First, the adsorption plate 100 is a plate body composed of the upper surface 110 and the bottom surface 120 as shown in Figures 4 and 5, the first inclined surface 130 and the upper surface 110 of the upper and lower light formed along the outline At least two vent holes 140 penetrating through the bottom surface 120, and the vent hole 140 is formed of a connection groove 150 formed in the bottom surface 120 to communicate with each other. In the present invention, the adsorption plate 100 may be the upper surface 110 may be flat, but preferably, the stepped portion 160 is formed inward of the inclined surface 130 to be configured so that the thickness of the outer portion is thinner than the central portion. It may be. In addition, although the adsorption plate 100 of the present invention may be composed of a single body, for example, as shown in Figure 5, the upper surface 110 and the bottom surface 120 of the central portion is composed of a separate body, the bottom surface 120 Silver may be made of soft plastic or soft rubber together with the outer part of the first inclined surface 130, and the upper surface 110 may be made of hard plastic.

Two or more, preferably four to twelve, vent holes 140 penetrate between the upper surface 110 and the bottom surface 120 of the adsorption plate 100, and these vent holes 140 are the bottom surface 120. Communicating with each other through the connection groove 150 formed in. The vent holes 140 and the connection grooves 150 preferably have a radial shape as shown in FIG. 4.

In addition, the housing 200 is formed in the periphery of the ceiling 210 to press the upper surface 110 of the adsorption plate 100 and the ceiling 210, as shown in Figure 6, the first of the adsorption plate 100 The vacuum wall 220 having the second inclined surface 230 in contact with the inclined surface 130 and the exhaust hole 240 that communicates with any one of the vent holes 140 of the suction plate 100 while penetrating the ceiling 210. ) And a recess 250 formed outside the upper end of the exhaust hole 240. The ceiling portion 210 of the housing 200 is a structure corresponding to the upper surface 110 of the suction plate 100, if the upper surface 110 is a flat structure, the ceiling portion 210 is configured to have a flat structure, the upper surface If the stepped part 160 is formed at 110, the stepped part 260 is also formed at the ceiling part 210. The stepped portions 160 and 260 hold the suction plate 100 so as not to swing in the housing 200, respectively. In addition, although the upper surface 110 and the ceiling portion 210 may be in close contact with each other, an uneven portion may be formed on at least one surface of the upper surface 110 and the ceiling portion 210 to form some spaces connected to each other.

Unlike the material of the housing 200, the vacuum wall 220 protruding around the ceiling 210 is made of a polyurethane-type polyurethane material, and contacts and corresponds to the first inclined surface 130 of the adsorption plate 100. It has a second inclined surface 230. The polyurethane constituting the vacuum wall 220 is a mixture of diol compounds having a molecular weight of 4,000 to 6,000 with respect to methylene diisocyanate at a ratio of 8 to 12, and a viscosity of 150 to 250 pcs is used. At this time, when the viscosity of the polyurethane is 150 pcs or less, the adhesive force is not enough to obtain a sufficient vacuum effect, on the contrary, when using more than 250 pcs, the adhesive force is increased but the adhesive surface is pressed or molded Insufficient property results in poor product quality.

Outside the ceiling 210, a protective wall 270 may be formed to protect the vacuum wall 220. At this time, care must be taken that the height of the protective wall 270 is not higher than the height of the vacuum wall 220. A recess 250 is formed at an upper end of the exhaust hole 240 penetrating the ceiling 210 of the housing 200, and the recess 250 has a one-way exhaust valve 300 and a closing cap 400. This is installed. The one-way exhaust valve 300 serves to block outside air from flowing into the housing 200 while exhausting the air inside the housing 200. Closing cap 400 is in close contact with the exhaust valve 300 to block the outside air flow into the housing 200, and closes the appearance of the housing 200.

The vacuum suction port of the present invention is installed using an exhaust pump (not shown). That is, the adsorption plate 100 and the housing 200 are in close contact with the adhered surface in the state where the closing cap 400 is not installed, and an exhaust pump is installed in the recess 250 to remove all the air inside the housing 200. Next, the exhaust pump is removed and the closing cap 400 is inserted into the recess 250 to install the vacuum suction port. The exhaust valve 300 installed in the recess 250 prevents external air from flowing into the housing 200 while removing the exhaust pump and installing the closing cap 400.

In the vacuum suction port of the present invention, unlike the conventional suction hole in which most of the suction plate 100 is separated from the adhered surface, the inside of the housing 200 is vacuumed while the bottom surface 120 of the suction plate 100 is in close contact with the adhered surface. Since the state is maintained, the friction force between the adsorption plate 100 and the surface to be deposited can be maintained to the maximum, and therefore, when a considerable load is applied in the direction parallel to the surface (when the suction port is installed on the wall, the direction of gravity of the earth). Exerts strong adsorption for a long time. In addition, the upper surface 110 of the suction plate 100 and the ceiling portion 210 of the housing 200, and the first inclined surface 130 and the second inclined surface 240 are completely in close contact with each other, and in particular, the vacuum wall 220. ), Which fills the minute grooves and unevenness of the adhered surface, and maintains a perfect vacuum state, so it maintains strong adsorption power even after a long time after installing the suction port.

In the present invention, the shape of the adsorption plate 100 and the housing 200 may be formed in a polygonal form, such as a rectangle, a pentagon, a hexagon, as well as a circle, and in particular, the shape of the housing 200 is a flower shape or a trumpet shape. By modifying according to the preferences of consumers, or character shapes, etc., more various products can be manufactured.

While the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited only to these embodiments, and various modifications of the design may be made by those skilled in the art within the scope of the claims. While attempts may be made, such easily craftable avoidance designs fall within the scope of the present invention.

In particular, the vacuum suction port according to the present invention has excellent adsorption power against load acting in a direction parallel to the surface to be deposited (when the suction port is installed on the wall), and the initial suction power is maintained for a long time. Therefore, it is expected that it can be used in various ways in homes, offices, schools, building exteriors, and industrial sites.

Claims (5)

A soft adsorption plate adhered to the adhered surface, and a hard housing covering the adsorption plate; The suction plate is a plate body consisting of a top surface and a bottom surface comprises a first inclined surface formed along an outline, at least two vent holes penetrating the bottom surface from the top surface, and a connection groove formed in the bottom surface so that these vent holes communicate with each other Become; The housing is any one of a ceiling for pressing the upper surface of the suction plate, a vacuum wall having a second inclined surface formed in the periphery of the ceiling and contacting the first inclined surface of the suction plate, and through the ceiling of the suction plate. An exhaust hole communicating with the groove, and a recess formed outside the upper end of the exhaust hole; The groove of the housing vacuum suction port, characterized in that the one-way exhaust valve to block the exhaust hole, the closing cap is installed. The vacuum suction port according to claim 1, wherein step portions corresponding to each other are formed on the upper surface of the suction plate and the ceiling of the housing, respectively. The vacuum suction port according to claim 1, wherein an uneven portion is formed on at least one of these surfaces so as to form a space connected between the upper surface of the suction plate and the ceiling of the housing. The method of claim 1, wherein the vacuum wall of the housing is a mixture of methylene diisocyanate and a diol compound having a molecular weight of 4,000 to 6,000 in a ratio of 1: 8 to 12, characterized in that made of a polyurethane having a viscosity of 150 to 250 pcs. Vacuum suction port. The vacuum suction port according to claim 1, wherein the housing is formed with a protective wall protruding along an outline of the ceiling.

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