JP2006316451A - Swing stopping mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To smoothly slidingly move a door body without splashing water such as rain water even if water such as rain water is accumulated in a guide groove while preventing the door body from being swung. <P>SOLUTION: This swing stopping mechanism preventing the swing of the door body 30 in the thickness direction comprises the door body 30 slidably moved while being suspended by a drive mechanism, the guide groove 40 formed at the lower part of the door body 30 extendedly within the slidable moving range of the door body 30, and a guide part 11 formed projectedly from the lower part of the door body 30 downward and fitted to the guide groove 40 with a play. A recessed groove 12 formed extendedly in the slidable moving direction of the door body 30 and passed therethrough and formed in a recessed groove shape opened downward. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an anti-sway mechanism for preventing a door body from shaking in the thickness direction, and more particularly to an anti-sway mechanism provided in an automatic door device.

  2. Description of the Related Art Conventionally, there is provided an automatic door device having a drive mechanism that slides a door body while suspending the door body above the door body. This type of automatic door device includes a detector and a controller, and is configured such that the controller controls the sliding movement of the door body when the detector makes an appropriate detection. In addition, this type of automatic door device is generally installed at a doorway of a building, and the doorway is opened and closed by sliding the door body.

  On the other hand, the drive mechanism attached above the door body is fixedly attached to the building. This drive mechanism includes a rail provided in accordance with the movement range of the door body, a suspension vehicle that moves on the rail and suspends the door body, a timing belt that moves the suspension vehicle, and a movement of the timing belt. And a pulley having an appropriate motor device. As the suspension vehicle moves, the suspended door body is also slid.

In this type of automatic door device, a steadying mechanism is provided for the purpose of preventing the door body from shaking in the thickness direction. That is, a guide groove extending along the moving direction of the door body is provided below the door body, and a guide portion protruding downward from the lower portion of the door body is provided. The guide portion is fitted in the guide groove with appropriate play so as to be movable in the guide groove (see Patent Document 1). In this type of automatic door device, the swing in the thickness direction of the door body is regulated by the guide portion and the guide groove into which the guide portion is fitted, thereby stabilizing the door body. It was designed to be able to slide.
JP-A-8-144624 (particularly FIG. 18)

  By the way, in this kind of automatic door apparatus, it may be installed in the location which faces the outdoors. In automatic door devices installed at locations facing the outdoors, rain often accumulates in the guide groove when it rains. When rainwater accumulates in such a guide groove, the guide portion that moves as the door body slides moves while pushing away the accumulated rainwater. As a result of the guide portion being pushed away, rainwater is splashed outward from the guide groove, causing a problem of contaminating human clothes standing in front of the door body. In addition, since the rainwater is pushed away, there is a problem that the door body cannot be smoothly slid.

  The present invention has been made in view of such circumstances, and an object thereof is an anti-sway mechanism provided in an automatic door device, and prevents rain or the like in a guide groove while preventing anti-sway of the door body. An object of the present invention is to provide an anti-sway mechanism that can smoothly slide and move a door body without causing water such as rain water to splash even when water has accumulated.

In order to solve the above-mentioned problems, the present invention provides a steadying mechanism of the following means.
That is, the invention according to claim 1 is a door body that is slid and moved while being suspended by a drive mechanism, a guide groove that is provided below the door body and extends in a range of sliding movement of the door body, An anti-sway mechanism that prevents the door body from shaking in the thickness direction, and has a guide portion that protrudes downward from the lower portion of the door body and is fitted in the guide groove with play. The guide portion is provided with a penetrating portion extending in the sliding movement direction of the door body and penetrating therethrough.

  In the steady rest mechanism according to the first aspect, the through portion is provided in the guide portion provided to project downward from the lower portion of the door body. This penetration part is provided through the guide part so that the hollow part extends in the sliding movement direction of the door body. The guide portion moves in the guide groove as the door body slides.

  Here, the automatic door device provided with this steadying mechanism may be affected by the external environment, and rainwater may accumulate in the guide groove. Even when such rainwater has accumulated, when the guide portion moves in the guide groove, the accumulated rainwater can pass through the penetrating portion. That is, the rainwater collected in the guide groove cannot be pushed away by the moving guide part. Therefore, the problem of rain water splashing that has been caused by being pushed away by the guide portion is solved. In addition, since rainwater in the guide groove cannot be pushed away, resistance to sliding movement of the door body is also reduced. Therefore, even if rainwater has accumulated in the guide groove, the door body can be smoothly slid.

  The guide groove is provided below the door body and extending in the range of sliding movement of the door body, and the guide portion is fitted in the guide groove with play. Therefore, the swaying in the thickness direction of the sliding door body is restricted by the guide portion being fitted into the guide groove, and even when the door body is slid by the drive mechanism. The door body can be stably slid by making it difficult to shake in the thickness direction.

  According to a second aspect of the present invention, in the steady rest mechanism according to the first aspect, the penetrating portion is formed in a concave groove shape opened downward.

  In the steady rest mechanism according to the second aspect, since the penetrating portion is formed in a concave groove shape opened downward, as described above, even if rainwater accumulates in the guide groove, the rainwater Can pass under the guide part. That is, the rainwater collected in the guide groove cannot be pushed away by the moving guide part. Therefore, the problem that the rainwater is sprung up caused by being pushed away by the guide portion is solved. In the case where the lower portion is configured to be opened as described above, it is particularly advantageous when rainwater collected in the guide groove is small in contact with the lower portion of the guide portion.

  According to the anti-sway mechanism according to the present invention, even when water such as rainwater accumulates in the guide groove while preventing the door body from being steady, the water such as rain water is splashed up. The door body can be smoothly slid and moved. Moreover, since rainwater is not splashed up, the clothes of a person standing in the vicinity of the door body are not soiled.

Hereinafter, the best embodiment of the automatic door device according to the present invention will be described with reference to the drawings.
FIG. 1 is a front view of an automatic door device provided with a steady rest mechanism according to the present invention, in which an outer lid of a drive mechanism is removed. Reference numeral 1 shown in FIG. 1 is an automatic door device provided with a steady rest mechanism according to the present invention. The automatic door device 1 is installed at an entrance of a building B, and includes a door body 30 that is slidable, a drive mechanism 20 that is attached to a wall B1 of the building B above the door body 30, A guide groove 40 provided below the door main body 30 and extending in the range of sliding movement of the door main body 30 is generally configured. And the doorway of this building B is opened and closed when this door main body 20 slide-moves. A fix plate 28 is provided at a position adjacent to the door body 30 (to the right in the drawing), and reference numeral 29 denotes a frame of the automatic door device 1.

  Further, as shown in the enlarged front view of the drive mechanism in FIG. 2, the drive mechanism 20 includes a base 21 fixedly attached to the wall B1 of the building B, and a slide of the door main body 30 below the base 21. A suspension rail 22 extending over the range of movement, a drive pulley 23 provided near one end of the base 21, and a driven pulley 24 provided near the other end of the base 21 are provided. A timing belt T is wound around the driving pulley 23 and the driven pulley 24, and the timing belt T is moved by the driving force of the driving motor built in the driving pulley 23.

  Further, the suspension belt 25 connected to the upper portion of the door body 30 is connected to the timing belt T. The suspension vehicle 25 is movable while the door body 30 is suspended by appropriate wheels 25 a provided on the suspension rail 22. That is, the suspension vehicle 25 is moved with the timing belt T moved by the drive pulley 23. The door body 30 is slid by the movement of the suspension vehicle 25 on the suspension rail 22. Moreover, the code | symbol 26 in a figure shows the auxiliary | assistant suspension vehicle provided with the wheel 26a and moving on the suspension rail 22. FIG. Unlike the suspension vehicle 25, the auxiliary suspension vehicle 26 is not connected to the timing belt T, but is connected to the upper portion of the door body 30, so that the door body 30 can be stably slid and moved. It is something to be made.

  On the other hand, the drive pulley 23 is connected to a control device (not shown). The control device controls driving of the driving pulley 23 in accordance with detection of a detector provided as appropriate. Here, the door body 30 is suspended by the suspension vehicle 25 and the auxiliary suspension vehicle 26. As a result, the door body 30 is slid in a floating state (floating state) where the lower part is not grounded. The “sliding direction of the door body 30 (hereinafter simply referred to as sliding movement direction)” is the left-right direction in FIG. 1, as indicated by the symbol D in the figure, and the door in the open sliding movement direction D1. The main body 30 moves so as to open, and the door main body 30 moves so as to close in the closing slide movement direction D2.

  Next, the principal part 10 of the steadying mechanism comprised in the lower part of the door main body 30 of this automatic door apparatus 1 is demonstrated, referring FIG. FIG. 3 is an enlarged view of the portion indicated by the symbol P in FIG. 1, and shows a cross section in the thickness direction of the door body 30. The “thickness direction of the door main body 30 (hereinafter simply referred to as the thickness direction)” is the direction of the thickness of the door main body 30 itself, as indicated by the symbol E in FIG. This also coincides with the direction orthogonal to the slide movement direction D shown in FIG.

  The main portion 10 of this steadying mechanism includes two guide portions 11 provided so as to protrude downward from the lower portion of the door main body 30, and as described above, below the door main body 30 and the door main body 30. It is comprised from the guide groove 40 extended and provided in the range of a slide movement. The two guide portions 11 are provided at an appropriate interval, and are configured in exactly the same manner. Therefore, only one guide portion 11 out of the two guide portions 11 will be described below. The guide portion 11 is movable in the guide groove 40 as the door body 30 slides.

  First, the guide groove 40 will be described. The guide groove 40 is provided below the door body 30 and extending in the range of sliding movement of the door body 30. As shown in FIGS. 1 and 3, the guide groove 40 includes a cover body 42 formed by bending stainless steel as a material into a perforated groove 41 that has been previously hollowed out in a substantially concave shape on the floor F surface. is set up. Further, the outer edge of the cover body 42 is formed with a bent portion 43 so that a surface is formed in the thickness direction E, and a groove portion 46 is constituted by the bottom surface portion 44 and the side wall surface 45 of the cover body 42. Has become.

  The guide portion 11 fitted in the guide groove 40 configured as described above is provided so as to protrude downward from the lower portion of the door body 30. That is, the width of the guide portion 11 is slightly smaller than the inner width of the groove portion 46 of the guide groove 40, the downward projecting length is slightly smaller than the depth of the groove portion 46 of the guide groove 40, and the sliding movement direction Is configured in a substantially rectangular parallelepiped shape with an appropriate length. The guide portion 11 is provided with a groove 12 extending in the slide movement direction D and penetrating therethrough and opened downward. The concave groove 12 is a groove cut out to a depth up to the horizontal level of the floor F surface. The concave groove 12 corresponds to the penetrating portion of the present invention. Further, in the guide portion 11, a portion facing the side wall surface 45 of the guide groove 40 is configured as the side wall portion 13.

  By configuring the guide portion 11 in this manner, the guide portion 11 is disposed in the guide groove 40 with a slight gap from the bottom surface portion 44 and the side wall surface 45 of the guide groove 40. That is, the guide portion 11 is fitted into the guide groove 40 with a moderate amount of play. In this way, the guide portion 11 can smoothly move in the guide groove 40 as the door body 30 slides. Further, since the guide portion 11 has the side wall portion 13 that faces the side wall surface 45 of the guide groove 40 as described above, when the door body 30 swings in the thickness direction E, The side wall portion 13 comes into contact with the side wall surface 45 of the guide groove 40, and the shaking is restricted.

  When the automatic door device 1 provided with the above-described steadying mechanism is installed at a location facing the outdoors, and when rainwater has accumulated in the above-described guide groove 40, this steadying mechanism has the following action. Play. 4A is a view showing an example in which rainwater is accumulated in the guide groove of the main part of the steady stop mechanism of FIG. 3, and FIG. 4B is a view of the main part of the steady stop mechanism of FIG. It is front sectional drawing.

  That is, in this steadying mechanism, as shown in FIGS. 4A and 4B, even when rainwater accumulates in the guide groove 40, the sliding movement of the door body 30 is accompanied. When the guide portion 11 moves in the guide groove 40, the accumulated rainwater W can pass through the concave groove 12. That is, the rainwater W collected in the guide groove 40 cannot be pushed away by the moving guide portion 11. Accordingly, the problem that the rain water W is splashed up that has been caused by being pushed away by the guide portion 11 is solved. In addition, since the rainwater W in the guide groove 40 cannot be pushed away, resistance to sliding movement of the door body 30 is also reduced. Therefore, even when rainwater W has accumulated in the guide groove 40, the door body 30 can be smoothly slid.

  Further, as shown in the figure, the concave groove 12 provided in the guide portion 11 is configured in a groove shape having an opening at the bottom, so that the guide portion 11 has moved in the guide groove 40 as described above. In this case, the rainwater W can pass under the guide portion 11. That is, the rainwater W collected in the guide groove 40 cannot be pushed away by the moving guide portion 11. Therefore, the problem that the rain water W is splashed up that has been caused by being pushed away by the guide portion 11 is solved. When the lower portion is configured to be opened as described above, the rainwater W accumulated in the guide groove 40 is particularly advantageous when the rainwater W is less in contact with the lower portion of the guide portion 11.

  As described above, when the steady rest mechanism is configured as described above, the rain water W has accumulated in the guide groove 40 while preferably preventing the door body 30 from shaking in the thickness direction E. However, the door body 30 can be smoothly moved without causing the rainwater to jump up. As a result, the rainwater splashes up, so that the clothes of persons standing near the door body are not soiled.

  In addition, in the said embodiment, the penetration part provided in the guide part and extended and penetrated in the slide movement direction was comprised by the concave groove 12 made into the groove shape opened below. However, the penetrating portion in the present invention is not limited to the groove shape opened downward, and any penetrating portion extending in the sliding movement direction D and being penetrated is included in the penetrating portion of the present invention. For example, the case where the principal part of the steady rest mechanism is configured as shown in FIG. 5 is also included.

  That is, in the main part 10A of the steadying mechanism shown in FIG. 5, an example in which the through part in the present invention is configured by a through hole 12A formed in a hole shape penetrating in the sliding movement direction of the door body 30. It is. Thus, when the penetration part of this invention is comprised as 12 A of through holes, it has the profit by which the side wall 13A which comprises 11 A of guide parts is supported by 14 A of bottom walls. In addition, the penetration part in this invention is not limited to what was comprised only by one hole like 12 A of through-holes shown in FIG. 5, Even if it is comprised by several fine holes, in this invention It does not deviate from the meaning of the penetration part. In addition, about the location comprised the same as the above-mentioned embodiment, the same code | symbol is attached | subjected and the description shall be abbreviate | omitted.

  Further, the present invention is not limited to the above-described embodiments, and appropriate selections can be made without departing from the spirit of the present invention. For example, the guide portion 11 may be provided with an appropriate wheel that rolls on the inner surface of the guide groove 40, or even if the internal configuration of the drive mechanism 20 is appropriately changed, It does not deviate from the purpose.

It is a front view of the automatic door apparatus provided with the steadying mechanism of this invention. It is an enlarged front view of a drive mechanism. It is sectional drawing which shows the principal part of a steadying mechanism. It is sectional drawing of the principal part of the steadying mechanism in which rainwater has accumulated in the guide groove. It is sectional drawing which shows other embodiment of the principal part of a steadying mechanism.

Explanation of symbols

1 Automatic door device 10 Stabilizing mechanism (main part of steadying mechanism)
DESCRIPTION OF SYMBOLS 11 Guide part 12 Concave groove 20 Drive mechanism 30 Door main body 40 Guide groove D Sliding movement direction E Thickness direction F Floor

Claims (2)

A door body that is slid while being suspended by a drive mechanism; a guide groove provided below the door body and extending in a range of sliding movement of the door body; and projecting downward from a lower portion of the door body. An anti-sway mechanism for preventing shaking in the thickness direction of the door body, and having a guide portion fitted with play in the guide groove,
An anti-sway mechanism according to claim 1, wherein the guide portion is provided with a penetrating portion extending in the sliding movement direction of the door body. The steadying mechanism according to claim 1, wherein the penetrating portion is formed in a concave groove shape opened downward.

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