JP4644257B2 - Slide automatic closing device and slide to which the device is attached - Google Patents

Abstract

Disclosed is a self-closing apparatus for a slide, which automatically moves a drawer to a completely closed position by tensile force of springs when the user moves the drawer toward the closed position. The self-closing apparatus includes a pair of springs, a moving pin, a moving pin guide, a plate-shaped movable member, and a fixed member. The moving pin includes a support pin portion, a support plate, and a guide protrusion. The moving pin guide includes a moving pin guide slot including a pin-receiving inlet portion and a pin engaging portion. The movable member includes a plate portion provided with a hole, a sliding rod formed integrally with the plate portion, and spring support portions. The fixed member includes a support base including spring support portions, an extension bar including movable member sliding portions and a moving pin guide portion, and a head.

Description

  The present invention relates to an automatic closing device for a slide and a slide to which the device is attached. More specifically, when a storage portion such as a drawer is moved to a sealed position, the storage portion is moved by means of an elastic biasing force of a spring. The present invention relates to a slide automatic closing device that automatically moves the device to a fully closed position and a slide to which the device is attached.

  A pair of slides are attached to the wall surface of the inner space of the main body where the storage unit is located so as to be symmetrical with each other, and the storage unit is slid with respect to the main body and is moved to a sealed position and an open position, The most representative slides are drawers such as desks, chests, and dressing tables. In addition, there is a storage part like a kimchi refrigerator, and this storage part is slid or sealed with respect to the main body. Anything that needs to be done can be used.

  Conventionally, it has been necessary to apply force to the storage unit until the storage unit is fully closed, and when the storage unit is applied with too much force, the storage unit is opened again due to impact repulsion with the main body. When the storage unit is provided, it is possible to automatically close the storage unit while preventing the storage unit from opening by providing a slide with a slight gradient inside the main body. Since the product is closed with a strong impact due to the load of the article stored in the container, there is a problem in that the main body, the storage unit itself, and the slide rail that supports the storage unit are damaged.

  In order to solve such a problem, the present applicant has disclosed a “fixing and guiding device for a storage device slider” in Korean Utility Model Registration No. 20-0287996. However, since this device uses a single hook-shaped spring, there is a problem that the hook portion of the spring is easily broken and cannot be used for a long time when used in a storage portion in which a heavy article is stored. .

  In addition, WO2001-82749 also discloses a self-closing slide device including a guide pin, a spring, an actuator, and a housing. The spring and actuator of this slide device are provided on a guide pin and are positioned so that the spring presses the actuator against the rear wall of the housing. The spring is in a compressed state at the open position of the slide and is in a normal state at the closed position of the slide, thereby preventing the spring from being extended and preventing the spring from breaking.

  The housing of the apparatus has opposing side walls, a rear wall, an upper wall, and a front wall, and has a structure in which all of guide pins, springs, and actuators can be accommodated in the housing. That is, the housing has a box-like structure, and the guide pin, the spring, and the actuator are located in the box. However, the housing having such a structure is not easy to manufacture and increases the manufacturing cost. In addition, in order to fix the housing to the fixing member (outer member) of the slide, a plurality of leg portions must be formed integrally with the housing, which further complicates manufacturing and further increases manufacturing costs. It is a factor.

DISCLOSURE OF THE INVENTION The present invention was developed in view of the above-mentioned problems, and its purpose is to attach a slide automatic closing device and a device thereof that are not broken early and the structure is simple. To provide a slide.

  In order to achieve the above object, according to the present invention, the slide automatic closing device is constituted by a pair of springs, a moving pin, a moving pin guide, a plate-like moving member, and a plate-like fixing member.

According to the present invention, the moving pin has a support rod, a support plate, and a guide projection, and the cross section thereof is preferably cylindrical, and the moving pin guide is formed by two inlet surfaces. A moving pin guide groove formed of a pin entrance portion and a moving pin locking portion formed by the first to third locking surfaces and having a locking groove 328 on the second locking surface 324; 1 connecting means. The moving member includes a plate-like portion having a groove at the center thereof, a sliding plate formed integrally with the plate-like portion, and a spring locking portion to which one of the springs is coupled. The fixing member includes a support portion having a spring engaging portion to which the other of the springs is coupled, an extension plate portion having a moving member sliding portion provided on both sides, and a moving pin guide portion provided on the inner side, a head And a second connecting means.

  Further, according to the present invention, the sliding plate of the moving member is composed of a protruding portion and a sliding groove, the moving pin guide portion of the fixed member is composed of a straight guide portion and a curved guide portion, and the moving pin guide is The fixed member is fixed to one end of the moving rail of the slider by the first connecting means and moves along the moving rail, and the fixing member is fixed to the fixed rail of the slide corresponding to the moving pin guide by the second connecting means. It is fixed to one end part.

  According to the present invention, the moving pin is fixed to the moving pin guide portion of the fixed member, and the sliding groove of the moving member is moved to the moving member of the fixed member while the supporting pin of the moving pin is inserted into the groove of the moving member. When the moving member slides along the sliding portion of the fixed member while being fixed to the sliding portion, the moving pin is moved integrally with the moving member along the moving pin guide portion of the fixed member.

  According to the present invention, when the slide is pulled out, the moving pin of the automatic closing device is positioned on the curved guide portion of the fixed member, and when the slide is retracted, the moving pin is the linear guide portion of the fixed member. The slide is automatically closed by moving between the positions by the elastic tension and contraction force of the spring. In the case of the automatic closing device according to the present invention, the spring used is not broken early, the structure is simple, the manufacturing cost is low, and the normal state is easily returned even when the operating state is abnormal. There is an advantage that you can.

  According to the present invention, it is preferable that both ends of the spring are tapered.

  Further, according to the present invention, it is preferable that the extension plate portion of the fixed member is adjacent to the moving member sliding portion and the protruding portion is provided in a direction along with the moving member sliding portion.

  Further, according to the present invention, it is preferable that the moving rail guide portion is provided on one surface of the moving member.

Effects of the Invention According to the present invention, the slide automatic closing device automatically seals the storage portion without applying any force to the storage portion until the storage portion is fully closed. In the case of adding, it is possible to prevent the storage portion from being opened again by an impact repulsive force.

  In addition, the spring used is not broken early, the structure is simple, the manufacturing cost is low, and even when the operating state is abnormal, it can be easily restored to the normal operating state.

  In addition, the automatic closing device can be operated smoothly by suppressing the vibration of the tip of the slide rail.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  Generally, the slide is composed of two members (including a fixed rail and a moving rail) or three members (including a fixed rail and two moving rails). The three-member slide 10 normally has a fixed rail (outer member) 800, two moving rails, that is, an intermediate moving rail (intermediate member) 900 that slides in the fixed rail 800, and a sliding movement in the intermediate moving rail 900. And an inner moving rail (inner member) 700 (see FIGS. 1 and 2). Between the rails, there is a ball retainer 950 having an appropriate length, and the ball retainer 950 holds the ball 955 so that the moving rails 700 and 900 can smoothly slide.

  As shown in FIG. 2, the slide 10 is a member that moves a storage portion 960 such as a drawer to a sealing position and an open position in a sliding manner with respect to a main body (not shown). By attaching the fixed rail 800 to an appropriate position of the main body, the slide 10 is provided, and the storage portion 960 is fixed to the inner moving rail 700 by fixing means such as screwing and fixing through the connecting hole 720. Accordingly, movement of the storage unit 960 results in sliding movement of the inner moving rail 700 and / or the intermediate moving rail 900. In the fully closed position of the storage unit 960, the slide 10 is completely folded (all the moving rails are pulled in), and in the fully open position of the storage unit 960, the slide 10 is completely expanded (all the moving rails are pulled out). Extended).

  The slide automatic closing device 20 according to the present invention is provided at the rearmost end of the fixed rail 800. A rail groove 910 that allows a part of the automatic closing device 20 to be accommodated in the longitudinal direction is provided at the rearmost end of the intermediate moving rail 900.

  FIG. 3 is a perspective view showing a preferred embodiment of the automatic closing device 20 according to the present invention. The device 20 includes a moving pin 400, a moving member 200, a fixed member 100, and a pair of springs 500. ing. The automatic closing device 20 includes a moving pin guide 300 that is fixed to the inner side of the inner moving rail 700 and detachably engages with the moving pin 400 (see FIG. 11).

  FIG. 4 is a perspective view of the moving pin. The moving pin 400 has a guide protrusion 410 on one side, a support rod 430 on the other side, and a support plate 420 at an intermediate portion thereof. A groove 411 is formed between the guide pin 410 and the support plate 420 in the moving pin 400. The support rod 430 of the moving pin 400 generally has a cylindrical shape.

  FIGS. 5a to 5c are a perspective view, a rear view, and a front view showing the moving pin guide 300, respectively. The moving pin guide 300 is provided with a moving pin guide groove 350 (FIG. 5a), and this moving pin guide groove 350 includes a moving pin inlet portion 310 and a moving pin locking portion 320 (FIG. 5b). The moving pin inlet portion 310 is formed by a first inlet surface 311 and a second inlet surface 312, and the moving pin locking portion 320 includes a first linear locking surface 323 and a second linear locking surface. 324 and a curved locking surface 325 are formed. A locking groove 328 for locking the moving pin is preferably formed on the second linear locking surface 324 of the moving pin inlet 310. Details of the moving pin guide groove 350 will be described later.

  The moving pin guide 300 is provided with a first connecting means for connecting the moving pin guide to the slide inner moving rail 700 (see FIG. 11). FIG. 5a shows a structure in which a groove 330 into which the connecting protrusion 710 of the moving rail 700 is inserted is formed as the first connecting means.

  In addition, the moving pin guide 300 is preferably formed with buffer portions 340 on opposite sides. The buffer portion 340 is formed so as to be slightly expanded outward, and a buffer groove 341 is formed around the buffer portion 340. Since the buffer portion 340 has a form that is spread outward, the back surface of the moving pin guide (here, the back surface means a connecting surface when the moving pin guide is fixed to the inner moving rail of the slide). In FIG. 5b, the buffer portion 340 is shown to protrude from both sides of the moving pin guide 300. In FIG. 5c, which shows the front of the moving pin guide, both side surfaces of the moving pin guide 300 are shown by straight lines. Has been. When the moving pin guide 300 is inserted into the inner moving rail 700 of the slide, the buffer portion 340 has an elastic buffering function (the self-closing device of the present invention including the moving pin guide is all made of a suitable plastic material. Thus, the buffer portion having such a configuration has an elastic action, and is easily inserted. However, once inserted, the moving pin guide 300 is prevented from being detached from the inner moving rail 700 of the slide. Has an effect. As described above, the moving pin guide 300 is easily inserted into the inner moving rail 700 and securely fixed by the first connecting means and the buffer 340.

  6a and 6b are a perspective view and a front view of the moving member 200, and FIG. 6c is a cross-sectional view of the moving member 200 as seen from the direction B of FIG. 6a. The moving member 200 includes a substantially square plate-like portion 210, a sliding portion 220 formed integrally with the plate-like portion 210, and spring engaging portions 212 provided on both sides of the plate-like portion 210. ing.

  The sliding portion 220 is provided with a protruding portion 221 and a U-shaped sliding groove 222, and the sliding groove 222 is engaged with a moving member sliding portion 121 of the fixed member 100 described later.

The spring locking portions 212 are formed on both sides of the plate-like portion 210 in the direction facing the connecting surface 223. In the present invention, the spring is not an annular spring having hooks formed at both ends, but a spring (tapered spring) 500 having a tapered portion 510 in the vicinity of both ends (see FIGS. 10a and 10b). . This is because the tapered spring 50 0, even if a heavy load in the storage portion of the slide was added as compared to the hook-shaped spring without spring breaks, can be used over a long period of time. According to the experiment conducted by the present applicant, as a result of experiments using a storage portion to which the same load was applied, the hook portion of the spring was broken when repeatedly used about 5,000 times. In the case of the taper shape, it has been shown that it has a service life more than five times that of the hook shape. 6A has a groove 215 into which the tapered portion 510 of the tapered spring 500 is inserted, and is formed so that the end of the tapered spring 500 can be inserted.

  The plate-like portion 210 is provided with a groove 211 at the center thereof. The support rod 430 portion of the moving pin 400 described in FIG. 4 is inserted into the groove 211 from the direction of the sliding groove 222. A support rod 430 is inserted into the groove 211 and the support rod moves in the left-right direction. At this time, the lateral length C of the moving pin guide portion 123 provided in the fixed member 100 (see FIG. 7a). It is preferable to have a length corresponding to. Further, it is preferable that an impact buffering portion 213 that serves to buffer an impact applied to the moving member 200 when colliding with another member is formed on one side of the plate-like portion 210.

  7a and 7b are a front view and a rear view of the fixing member 100. Here, the rear surface means that when the fixing member 100 is fixed to a slide fixing rail 800 (see FIG. 11), the connection thereof is shown. Say the face. The fixing member 100 includes a support portion 110, an extension plate portion 120 formed integrally with the support portion 110, and a head portion 130 formed integrally with the extension plate portion 120, and has a plate-like shape as a whole. It has a form.

The supporting portion 110, on both sides of a direction opposite to the locking stepped 119, the spring engaging portion 111 of one side of the spring 500 is engaging is provided. This spring locking portion 111 also has a groove 115 into which the tapered portion 510 of the tapered spring 500 is inserted, and has a structure corresponding to the spring locking portion 212 of FIG.

  A moving pin guide portion 123 is provided in the longitudinal direction inside the extension plate portion 120, and the moving pin guide portion 123 includes a straight guide portion 124 and a curved guide portion 125. The moving pin 400 is fixed to the moving pin guide portion 123 to perform a sliding motion. On both side surfaces of the extension plate portion 120, a moving member sliding portion 121 into which the sliding groove 222 of the moving member 200 is inserted is provided. The moving member sliding portion 121 is formed to have a thickness corresponding to the size of the sliding groove 222, which is thinner than the thickness of the body of the extension plate portion 120. Further, as shown in FIG. 8 which shows a partial cross-sectional view taken along line A-A of FIG. 7A, the extension plate 120 is provided with a protrusion 122 adjacent to the moving member sliding portion 121 and in a direction along with this. It has been. The protrusion 122 acts as a support that prevents the moving member 200 from being bent or twisted even when the moving member 200 receives a compressive force acting on both sides or in the longitudinal direction. The extension plate 120 is formed with a buffer notch 126 on one side of the linear guide 124 of the moving pin guide 123. The buffer notch 126 is formed to communicate with the moving pin guide 123 in a direction parallel to the moving pin guide 123, and a support protrusion 127 is formed between the moving pin guide 123 and the buffer notch 126. The support protrusion 127 is preferably provided with a protrusion 128 that prevents the support protrusion from being twisted toward the back surface of the fixing member 100. The operation of the buffer notch 126 and the protrusion 128 will be described later.

  An impact buffering portion 132 is preferably formed on the head portion 130 of the fixing member 100. The shock buffer 132 acts to absorb the shock when it collides with another member of the slide (for example, in the case of a three-member slide, an intermediate moving rail) (a collision occurs when the slide reaches the retracted position). .

  The support part 110 and the head part 130 of the fixing member 100 are formed with second connecting means for connecting the fixing member to the fixed rail 800 of the slide. Here, connection holes 112 and 131 for rivet connection as second connection means are shown.

  Hereinafter, the relationship and operation between the above-described components will be described.

  First, the moving pin 400 is fixed to the moving pin guide portion 123 of the fixed member 100. FIG. 9 is a perspective view showing a state in which only the moving pin 400 is inserted into the fixed member 100. In this connection, the groove 411 formed by the guide protrusion 410 of the moving pin 400 and the support plate 420 is inserted so that the groove 411 is fitted to the moving pin guide part 123 of the fixing member 100. It is configured to be inserted so that it faces the back surface and the support rod 430 faces the front surface. At this time, the insertion is easily performed by pushing the guide protrusion 410 of the moving pin 400 into the moving pin guide part 123 while pushing the support protrusion 127 toward the buffer notch 126 of the fixing member 100. When the moving pin 400 is inserted into the moving pin guide portion 123, the support rod 430 of the moving pin 400 is inserted into the groove 211 of the moving member 200, and the moving member sliding portion of the fixed member 100 is inserted into the sliding groove 222 of the moving member 200. By inserting 121, the moving member 200 is coupled to the fixed member 100. Finally, one of the springs 500 is connected to the spring locking part 111 of the fixed member 100, and the other of the springs 500 is connected to the spring locking part 212 of the moving member 200. FIG. 3 is a perspective view showing the state configured as described above. With such a configuration, the moving member 200 slides along the moving member sliding portion 121 of the fixed member, and the moving pin 400 moves along the moving pin guide portion 123 of the fixed member 100 together with the moving member. To come.

  FIGS. 10a and 10b are front views of the automatic closing device showing a state in which the fixed member 100, the moving member 200, the moving pin 400, and the spring 500 are combined. FIG. FIG. 10B shows a state where the moving pin guide part 123 of the fixed member 100 is positioned at the end of the linear guide part 124, and FIG. 10B shows a state where the moving pin 400 is locked to the curved guide part 125 of the moving pin guide part 123. FIG. The moving pin 400 moves between these two positions. When the moving pin 400 is locked to the curved guide portion 125, the spring 500 is pulled to the maximum as shown in the drawing.

  As described above, the fixed member 100 in which the movable pin 400, the movable member 200, and the spring 500 are coupled is fixed to the fixed rail 800 of the slide by the second connecting means, and the movable pin guide 300 is the first pin. Are fixed to the inner moving rail 700 of the slide.

Next, the operation of the automatic closing device according to the present invention will be described with reference to FIGS. 11 to 13, the illustrated slide is a three-member slide having two moving rails (an intermediate moving rail and an inner moving rail) and one fixed rail. However, for the sake of simplicity, the inner moving rail 700 is shown. The intermediate moving rail between the fixed rail 800 and the fixed rail 800 is not shown. For convenience, the storage portion and the main body wall are omitted, and only the slide is shown and described. is fixed to the fixed rail 800, the moving pin guide 300 is not visible from the outside is fixed to the inside of the inner movable rail 700 faces the stationary member 100, are shown here for convenience, the moving pin guide 300 with a solid line.

  FIG. 11 shows a state in which the fixing member 100 is rivet-connected to the fixed rail 800 of the slide and the moving pin guide 300 is fixed to the connecting protrusion 710 of the inner moving rail 700 of the slide and separated from each other. Yes. That is, when the storage portion is pushed from the open position to the sealed position, the slide inner moving rail 700 is in the retracted position from the drawn position, and is inserted into the groove 211 of the moving member 200 and integrated with the moving member 200. The moving pin 400 that moves in the state is locked to the curved guide portion 125 of the moving pin guide portion 123 of the fixed member 100, and the spring 500 is pulled to the maximum.

  FIG. 12 is a diagram illustrating a state in which the inner moving rail 700 is further moved to the retracted position, and the moving pin guide 300 is coupled to the moving pin 400 that is locked to the curved guide portion 125, particularly the support rod 430 of the moving pin 400. It is. The support rod 430 of the moving pin 400 is inserted into the moving pin inlet portion 310 formed by the first inlet surface 311 and the second inlet surface 312, followed by the first linear locking of the moving pin locking portion 320. It moves along the surface 323 and the second linear locking surface 324. By this movement, the moving pin 400 is detached from the state where it is locked to the curved guide portion 125. When the moving pin 400 completes detachment from the curved guide portion 125, the moving member 200 and the moving pin 400 that moves together with the moving member 200 are moved along the straight guide portion 124 by the tensile force of the spring 500 immediately. Until the connecting surface 223 (refer to FIG. 6a) of the fixing member 100 is fixed to the locking step 119 of the fixing member 100, it moves to the fully retracted position along the straight guide portion 124 of the fixing member 100. Since the support rod 430 of the moving pin 400 is locked on the second linear locking surface 324, the moving pin guide 300 moves along the moving pin 400. This results in automatically moving the inner moving rail 700 of the slide to the fully retracted position.

  According to the present invention, as described above, the locking groove 328 is formed in the second linear locking surface 324. The locking groove 328 is formed at a position where the support rod 430 of the moving pin 400 is locked at the moment when the moving pin 400 is almost completely detached from the curved guide portion 125. In this manner, when the moving pin 400 finishes detaching from the curved guide portion 125, the support rod 430 of the moving pin 400 is safely locked in the locking groove 328 and moved along the linear guide portion 124. It becomes like this.

  FIG. 13 is a view showing a state in which the moving pin guide 300 is coupled to the support rod 430 of the moving pin 400 and is in the fully retracted position of the slide (ie, the storage portion is completely closed) by the force of the spring 500. is there.

  The slide is pulled out in the reverse order of the above process. When the inner moving member of the slide is pulled out (that is, the storage portion is pulled out), the moving pin 400 that was in the state shown in FIG. 13 is straight in a state where the supporting pin 430 of the moving pin is locked in the locking groove 328. When the guide rod 124 moves along the guide portion 124 and arrives at the curved guide portion 125, the support rod 430 is disengaged from the locking groove 328 in the direction of the moving pin inlet portion 310 along the second linear locking surface 324. Moving. When the support rod 430 moves along the second linear locking surface 324 and arrives at the moving pin inlet portion 310, the moving pin 400 is locked to the curved guide portion 125 of the moving pin guide portion 123 of the fixed member 100. Next, in the continuous movement to the drawing position, the moving pin 400 leaves the moving pin inlet portion 310 of the moving pin guide 300 and is separated from the moving pin guide 300. It becomes like this. The state where the moving pin guide 300 is separated from the moving pin 400 and goes to the drawing position corresponds to the state shown in FIG.

  As described above, when the slide inner moving rail 700 is in the pulled-out position, the moving pin 400 is locked to the curved guide portion 125 of the fixed member 100, and the inner moving rail 700 moves to the retracted position. When moving, the moving pin locking part 320 of the moving pin guide 300 fixed to the inner moving rail 700 is coupled to the support rod 430 of the moving pin 400 and pulled by the elastic biasing force of the spring 500, By moving along the straight guide portion 124 of the fixed member 100 until it moves along the straight guide portion 124 and the connecting surface 223 of the movable member 200 is fixed to the locking step 119 of the fixed member 100, Can be automatically moved to the fully closed position.

  As described above, the slide moving rails 700 and 900 are pulled in or pulled out in cooperation with the ball retainer 950. At this time, the moving rail is supported only by the ball retainer 950. When the tip of the sword moves, it begins to shake. Such a vibration at the tip of the moving rail particularly occurs when the moving pin guide 300 is coupled to the moving pin 400 from the state illustrated in FIG. 11 to the state illustrated in FIG. 12 where the moving pin guide 300 is coupled to the moving pin 400. Can cause obstacles. That is, the vibration at the tip of the moving rail may prevent the automatic closing device from operating smoothly.

  FIG. 14A is a diagram showing another embodiment of the moving member, and is a perspective view of the moving member 200 ′ provided with the moving rail guide portion 270 for preventing the tip of the moving rail from vibrating. 14b is a cross-sectional view seen from the direction B in FIG. 14a.

  As shown in the figure, the moving rail guide portion 270 is formed on a surface facing the surface of the moving member 200 ′ in which the U-shaped sliding groove 222 is formed. The moving rail guide portion 270 is constituted by a holding plate 272 formed integrally with the moving member 200 '. The holding plate 272 is preferably a quadrangular prism, but may be a triangular prism. The holding plate 272 is formed to have a width corresponding to the width of the inner moving rail 700. At this time, the length of the holding plate 272 in the longitudinal direction must have an appropriate length for guiding the inner moving rail 700, and is preferably formed over the entire length of the moving member 200 '. The holding plate 272 serves to suppress vibration of the inner moving rail 700 in the left-right direction. Other portions of the moving member 200 ′ are the same as those of the embodiment of the moving member 200.

  A guide flange 274 is preferably formed at the end of the holding plate 272. This guide flange 274 should be formed on an appropriate height of the holding plate 272. The guide flange 274 serves to suppress vibration of the inner moving rail 700 in the vertical direction.

  On the other hand, when the moving pin guide 300 is in the retracted position depending on the case during use, the moving pin 400 is not in the state of being locked to the curved guide portion 125 (the state of FIG. 11), that is, the fully retracted position, In some cases, the movement along the straight guide portion 124 is completed (the state shown in FIG. 13). This is because, when the slide is in the pulled out position, another member bites into the slide due to carelessness of the user, and the other member is engaged with the moving pin 400 by the curved guide portion 125. Even in the case of such an abnormal operation state, the slide automatic closing device according to the present invention can be easily returned to the original normal operation position.

  When in the above-described state, that is, as shown in FIG. 15, when the moving pin guide 300 comes to the retracted position, the abnormal operation in which the moving pin 400 has finished moving along the linear guide portion 124. In this state, the moving pin guide 300 is moved to the retracted position by a force that the user pushes the storage portion into the retracted position and moves, and the second entrance surface 312 of the moving pin guide 300 supports the moving pin 400. Fits 430. Since the second entrance surface 312 is a surface inclined in the direction of about 45 °, the continuous movement of the moving pin guide 300 to the retracted position causes the support rod 430 of the moving pin 400 to move the buffer notch of the fixing member 100. Force to be pushed out to the portion 126 is generated. This force moves the free end of the support protrusion 127 to the buffer notch 126. This movement causes the moving pin 400 to move in the direction of the buffer notch 126, which causes the moving pin 400 to move in the direction of the moving pin locking portion 320 through the second inlet surface 312 of the moving pin guide 300. As a result, the moving pin 400 finally enters the moving pin locking portion 320 through the moving pin inlet portion 310 of the moving pin guide 300. Thus, when the moving pin 400 enters the moving pin locking part 320 of the moving pin guide 300, the automatic closing device for slide according to the present invention returns to the original normal operating position (state of FIG. 13). Become.

  At this time, as described above, the support protrusion 127 is preferably formed with a protrusion 128 that prevents the support protrusion from being twisted in the back surface direction of the fixing member 100 (see FIG. 7b). The protrusion 128 is used when the slide automatic closing device according to the present invention returns from the abnormal state to the normal operation state as described above, that is, when the movable pin guide 300 is continuously retracted. When the movement generates a force for pushing the support rod 430 of the moving pin 400 to the buffer notch 126 of the fixed member 100 and moves the free end of the support protrusion 127 to the buffer notch 126, the support protrusion 127. Is not twisted and moves linearly to the buffer notch 126. If the support protrusion 127 is severely twisted, the moving pin 400 may leave the linear guide portion 124 of the moving pin guide portion 123 of the fixed member 100 and enter the buffer cutout portion 126 in some cases. Until the slide is disassembled and returned to the normal position, the automatic closing device cannot operate normally any more. The protrusion 128 prevents the support protrusion 127 from being twisted by applying a repulsive force by contacting the inner surface of the fixed rail 800 of the slide when the support protrusion 127 receives a twisting force.

  Although the present invention has been described above using only one slide, it is understood by those skilled in the art that the original purpose cannot be achieved unless the two slides are installed symmetrically. Anyone should understand. At this time, when the two slides are installed symmetrically, the self-closing device of the present invention is also manufactured symmetrically, that is, the fixed member 100 and the moving pin guide 300 are manufactured in a left-right shape in pairs with each other. Must be used.

  Although the automatic closing device according to the present invention has been described using a three-member slide including two moving rails and one fixed rail, the same applies to a two-member slide using only one moving rail and one fixed rail. It should be understood by anyone skilled in the art that it can be applied to.

  In addition, the automatic closing device according to the present invention is preferably made of a plastic material having appropriate strength and elasticity, but is not limited thereto.

  Further, the moving pin guide constituting the automatic closing device according to the present invention is not separately manufactured and fixed to the end of the moving rail, but is formed on the end of the moving rail by means such as a punch. May be.

It is sectional drawing of a 3 member slide. FIG. 6 is a perspective view showing a three-member slide to which an automatic closing device according to the present invention is attached. 1 is a perspective view showing an automatic closing device according to the present invention. It is a perspective view of a movement pin. 5a to 5c are a perspective view, a rear view, and a front view of the moving pin guide, respectively. 6a and 6b are a perspective view and a front view of the moving member, and FIG. 6c is a cross-sectional view of the moving member as seen from the direction B in FIG. 6a. 7a and 7b are a front view and a rear view of the fixing member. It is the fragmentary sectional view by the AA line of FIG. It is a perspective view which shows the state in which only the movement pin was fixed to the fixing member. 10A and 10B are views showing a state where the moving pin is positioned at the end of the linear guide portion of the moving pin guide portion of the fixed member and a state where the moving pin is locked to the curved guide portion. It is a figure which shows the state from which the movement pin was isolate | separated from the movement pin guide. It is a figure which shows the state which a movement pin guide couple | bonds with the movement pin currently latched by the curve guide part. It is a figure which shows the state which a movable pin guide couple | bonds with a movable pin and exists in the slide full retraction position with the force by a spring. FIG. 14A is a perspective view showing another embodiment of the moving member, and FIG. 14B is a cross-sectional view of the moving member seen from the direction B of FIG. 14A. It is a figure which shows what the automatic closing device exists in the abnormal operation state.

Claims (12)

A pair of springs ( 500 ) ;
A cylindrical moving pin ( 400 ) having a support rod ( 430 ) , a support plate ( 420 ), and a guide protrusion ( 410 ) ;
Moving pin inlet portion formed by two inlet surfaces (311, 312) and (310) are formed in the first to third three engagement face (323, 324, and 325), the second locking surface A moving pin guide groove ( 350 ) composed of a moving pin locking portion ( 320 ) provided with a locking groove (328) in (324), and a moving pin guide ( 300 ) having a first connecting means; ,
One of the plate-like portion ( 210 ) provided with the groove ( 211 ) in the central portion thereof, the sliding plate ( 220 ) formed integrally with the plate-like portion ( 210 ) , and the spring ( 500 ) is coupled. A moving member ( 200 ) having a spring locking portion ( 212 ) ;
A support part ( 110 ) having a spring locking part ( 111 ) to which the other of the springs ( 500 ) is coupled, a moving member sliding part ( 121 ) provided on both sides, and a moving pin guide part ( 123 ) provided on the inner side provided) and an extension plate portion having a (120), the head portion (130), a plate-shaped fixing member and a second coupling means (100), a
The spring ( 500 ) comprises a tapered spring having a tapered portion ( 510 ) in the vicinity of both ends,
Sliding board of the moving member (200) (220) is configured de protruding portion (221) sliding groove and (222),
The moving pin guide part ( 123 ) of the fixed member ( 100 ) is composed of a straight guide part ( 124 ) and a curved guide part ( 125 ) ,
The moving pin ( 400 ) is fixed to the moving pin guide part ( 123 ) of the fixed member ( 100 ) , and the support pin of the moving pin ( 400 ) is inserted into the groove ( 211 ) of the moving member ( 200 ) . sliding grooves of the movable member (200) (222) is fixed to the moving member sliding portion (121) of the fixed member (100), when the moving member (200) is gliding along a sliding portion of the fixing member (121) The moving pin ( 400 ) moves integrally with the moving member ( 200 ) and moves along the moving pin guide portion ( 123 ) of the fixed member,
Moving pin guide (300) by the first connecting means is fixed to one end of the moving rail of the slide, to move along the moving rail, the fixing member, the second coupling means, the moving pin guide ( 300 ), and is fixed to one end of a fixed rail of the slide. Grooves provided in the plate-like portion (210) of the moving member (220) (211) is a length corresponding to the moving pin guide portion horizontal length of (123) of the fixed member (100) (C) The slide automatic closing device according to claim 1, wherein the slide automatic closing device is provided. The first connecting means is a groove ( 330 ) connected to the connecting projection ( 710 ) of the moving rail, and the second connecting means is a rivet connection ( 112, 131 ). The automatic closing device for slides according to 1. A buffer notch portion ( 126 ) is formed in the extension plate portion ( 120 ) of the fixed member ( 100 ) , and is formed so as to communicate with the linear guide portion ( 124 ) of the moving pin guide portion ( 123 ) in a parallel direction. , A support protrusion ( 127 ) is formed between the movable pin guide part ( 123 ) and the buffer notch ( 126 ), and a protrusion ( 128 ) that prevents the support protrusion from twisting on the support protrusion ( 127 ). The automatic closing device for sliding according to claim 1, wherein: A buffer part ( 340 ) and a buffer groove ( 341 ) are formed on both sides of the moving pin guide ( 300 ) , and the buffer part ( 340 ) is formed so as to be spread outward and has an elastic function. The slide automatic closing device according to claim 1. The extension plate ( 120 ) of the fixed member ( 110 ) is provided with a protrusion ( 122 ) in a direction adjacent to the moving member sliding portion ( 121 ) and aligned therewith. , Automatic closing device for slide. The automatic closing device for slide according to claim 1, wherein a moving rail guide part ( 270 ) is provided on one surface of the moving member ( 200 ) . The moving rail guide part ( 270 ) is constituted by a holding plate ( 272 ) formed integrally with the moving member ( 200 ) , and a guide flange ( 274 ) is provided at an end of the holding plate ( 272 ). The automatic closing device for slide according to claim 7 characterized by the above-mentioned. The slide includes a fixed rail ( 800 ) , two moving rails ( 700, 900 ), and a ball retainer ( 950 ) that is provided between the rails and links the moving rails so that the moving rails can slide.
A slide with an automatic closing device attached thereto, wherein the automatic closing device according to any one of claims 1 to 8 is attached to the slide. 10. A self-closing device according to claim 9 , characterized in that a rail groove ( 910 ) in which a part of the self-closing device is accommodated in the longitudinal direction is provided at the end of the moving rail ( 900 ) . Slide. The slide comprises a fixed rail, and one moving rail, provided between these rails, according to claim 9, movable rail is characterized in that it comprises, a ball retainer to link them to be sliding movement , Slide with automatic closing device attached. The slide according to claim 9 , wherein the slide is a Kimchi refrigerator slide.

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