KR102646029B1 - Slide module - Google Patents

Abstract

One embodiment of the present invention includes a housing in which a first guide rod and a second guide rod are formed, a first slider that moves along the first guide rod and engages with an external activator, and a first slider that moves the first slider in a closing direction. 1. A closing unit having an elastic member and a damper to buffer the movement of the first slider, a second slider that moves along the second guide rod and engages the external activator, and a second slider that moves the second slider in the opening direction. 2 elastic members, and a push-open unit having a locking mechanism that locks or unlocks the operation of the second elastic member as the external activator is introduced, and when closed, the closing unit is operated by the external activator to self-close. A slide module that performs a closing (self-closing) function and when opened, the push-open unit is unlocked when pressed by a push operation while the external activator is inserted and performs a push-open function. to provide.

Description

Slide module {SLIDE MODULE}

The present invention relates to a slide module, and more specifically, to a slide module having a self-closing function and a push-open function.

In general, a sliding type storage body is provided in a main body such as furniture, a refrigerator, or various organizers so that it can be opened and closed in a sliding manner to store necessary items.

This sliding type storage body is provided with a space for installing the storage body in the main body, and is opened by sliding rails that are placed on the inner wall of the installation space and on both sides of the storage body to enable sliding movement through mutual rolling contact. Or it operates closed.

Meanwhile, this sliding type storage body may be equipped with a push open device. For example, when the user wants to open the storage body as needed, the storage body partially protrudes from the main body due to the elastic response of the push-open device when the storage body is pushed, and the user can use it by pulling it with his hand.

Additionally, this sliding type storage body may be equipped with a device. For example, when the user wants to close the storage body due to need, the storage body is automatically retracted by the self-closing device by just pushing the storage body a predetermined distance, and the user does not have to push the storage body all the way.

However, according to the prior art, the push opening device and the self-closing device are provided as separate devices in the sliding type storage body, causing problems such as space limitations or deterioration in operability when installing the storage body.

Korean Patent Publication No. 10-1742643 (May 26, 2017)

The present invention is intended to solve the problems of the prior art described above, and the purpose of the present invention is to provide a slide module with a self-closing function and a push-open function.

In order to achieve the above object, one aspect of the present invention is a housing in which a first guide rod and a second guide rod are formed, a first slider that moves along the first guide rod and engages with an external activator, and the first guide rod. a closing unit having a first elastic member that moves the slider in a closing direction and a damper that cushions the movement of the first slider, and a second slider that moves along the second guide rod and engages the external activator, the second a push-open unit having a second elastic member that moves the slider in an opening direction, and a locking mechanism that locks or unlocks the operation of the second elastic member as the external activator is introduced, and when closed, the closing unit It is operated by the external activator to perform a self-closing function, and when opened, the push-open unit is unlocked when pressed by a push operation while the external activator is inserted, thereby pushing-opening. Provides a slide module that performs functions.

In one embodiment of the present invention, the closed section is divided into a lead-in section (A) and a self-closing section (B), and in the lead-in section (A), the external activator is connected to the second slider by an external force. After being first coupled, it moves until it is coupled with the first slider, and in the self-closing section (B), the external activator is coupled with the first slider and the second slider and the first elastic member is moved. It may be a slide module, characterized in that it moves in the closing direction by elastic force.

In one embodiment of the present invention, the open section is divided into a push section (C) and an open section (D), and when the external activator is pushed a certain distance by an external force in the push section (C), the 2 The elastic member is unlocked and can move in the open direction, and in the open section (D), the external activator is combined with the first slider and the second slider and the elastic force of the second elastic member It may be a slide module, characterized in that it moves in the opening direction.

In one embodiment of the present invention, the push-open unit has one or more operating protrusions protruding from the outer peripheral surface, and one or more locking protrusions protruding from the outer peripheral surface at a predetermined distance from the operating protrusions, and is fixedly installed in the housing. A shaft, one side of which is coupled to the second slider, a movable carriage that is inserted through the shaft and moves along the shaft, is engaged with the movable carriage for a certain section and moves along the shaft, and the shaft is inserted through and moves along the shaft; , a rotator that rotates in one direction by the operating protrusion when retracted and thereby repeatedly locks or unlocks with the locking protrusion, and the shaft is inserted through and moves along the shaft, and one end of the second elastic member and It may be a slide module that is connected and further includes a support member that supports the operation of the second elastic member as the rotator moves.

In one embodiment of the present invention, the rotator may be a slide module, characterized in that it includes one or more ratchet protrusions formed on the inner peripheral surface, and one or more passage parts formed between the ratchet protrusions.

In one embodiment of the present invention, the ratchet protrusion has both ends formed in a beveled shape, a first ratchet protrusion engaging with the operating protrusion and the locking protrusion, and disposed parallel to the first ratchet protrusion, and both ends having a beveled shape. It is formed of a second ratchet protrusion engaged with the operating protrusion and the locking protrusion, and a blocking protrusion that connects the first ratchet protrusion and the second ratchet protrusion and is configured to engage the locking protrusion when locked. It may be a slide module.

In one embodiment of the present invention, one end of the operating protrusion is formed to correspond to the inclined surface shape of the first ratchet protrusion and the second ratchet protrusion, and one end of the stopping protrusion is formed to correspond to the first ratchet protrusion and the second ratchet protrusion. It may be a slide module, characterized in that it is formed to correspond to the inclined surface shape of.

In one embodiment of the present invention, the rotator includes a plurality of outer protrusions formed in a circular shape on the outer peripheral surface, and the moving carriage is formed on the inner peripheral surface and the outer protrusions are caught in the lead-in section (A). A locking part that allows the rotator to be pulled in together, and a guide part formed on the inner peripheral surface that guides the rotator to move relative to the inside in the self-closing section (B) when the lock is released by rotating the rotator in one direction; , It may be a slide module, wherein the rotator is rotated by the operating protrusion when moving from the lead-in section (A) to the self-closing section (B).

In one embodiment of the present invention, the locking mechanism may be a slide module, characterized in that it is performed by interaction between the shaft and the rotator.

According to one aspect of the present invention, both the self-closing function and the push-open function can be performed by configuring the closing unit and the push-open unit into one module.

Additionally, the closing unit performs a self-closing function using the first elastic member and a soft closing function using a damper to enable smooth introduction of the external activator.

Additionally, the push-open unit can improve user convenience by locking and unlocking the slide module through a push operation.

The effects of the present invention are not limited to the effects described above, and should be understood to include all effects that can be inferred from the configuration of the invention described in the detailed description or claims of the present invention.

Figure 1 is a perspective view of a slide module according to an embodiment of the present invention.
Figure 2 is an exploded view of a slide module according to an embodiment of the present invention.
Figure 3 is a perspective view of a housing according to an embodiment of the present invention.
Figure 4 is a top and rear view of a housing according to an embodiment of the present invention.
Figure 5 is a perspective view of a closing unit according to an embodiment of the present invention.
Figure 6 is an exploded view of a closing unit according to an embodiment of the present invention.
Figure 7 is a plan view and a perspective view of a push-open unit according to an embodiment of the present invention.
Figure 8 is an exploded view of a push-open unit according to an embodiment of the present invention.
Figure 9 shows a rotator according to an embodiment of the present invention.
Figure 10 shows a moving carriage according to one embodiment of the present invention.
Figure 11 shows the operation process when closing the slide module according to an embodiment of the present invention.
Figure 12 shows the operation process when opening the slide module according to an embodiment of the present invention.
Figure 13 shows a locking mechanism according to one embodiment of the present invention.
Figure 14 shows the operation process when forcibly withdrawing the slide module according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the attached drawings. However, the present invention may be implemented in various different forms and, therefore, is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts that are not related to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only cases where it is “directly connected,” but also cases where it is “indirectly connected” with another member in between. . Additionally, when a part "includes" a certain component, this does not mean that other components are excluded, but that other components can be added, unless specifically stated to the contrary.

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

Figure 1 is a perspective view of a slide module according to an embodiment of the present invention, and Figure 2 is an exploded view of a slide module according to an embodiment of the present invention.

Referring to Figures 1 and 2, the slide module 1000 of the present invention includes a housing 100, a closing unit 200, and a push-open unit 300.

More specifically, the slide module 1000 includes a housing 100 in which a first guide rod 111 and a second guide rod 121 are formed, moves along the first guide rod 111 and uses an external activator 10. A closing unit ( 200). In addition, the slide module 1000 includes a second slider 310 that moves along the second guide rod 121 and engages with the external activator 10, and a second slider 310 that moves the second slider 310 in the opening direction. It includes two elastic members 350 and a push-open unit 300 having a locking mechanism that locks or unlocks the operation of the second elastic member 350 as the external activator 10 is introduced.

At this time, the closing unit 200 is configured to perform a self-closing function by being operated by the external activator 10 when closed. In addition, the push-open unit 300 is configured to perform a push-open function by being unlocked when pressed by a push operation while the external activator 10 is inserted during opening.

That is, the slide module 1000 is configured so that the self-closing function and the push-open function operate as one module.

The slide module 1000 can be installed directly on the main body of furniture, refrigerators, or various organizers. Alternatively, the slide module 1000 may be indirectly installed on the main body by being coupled to a fixed rail installed on the main body. The activator 10 that operates the slide module 1000 may be directly installed on a drawer body that is provided in the main body to be able to open and close in a sliding manner. Additionally, the activator 10 may be indirectly installed on the main body by being coupled to a moving rail installed on the drawer body.

Figure 3 is a perspective view of a housing according to an embodiment of the present invention, and Figure 4 is a top view and a rear view of the housing according to an embodiment of the present invention.

Referring to Figures 3 and 4, the housing 100 accommodates the closing unit 200, the first receiving portion 110 in which the first guide rod 111 is formed, and the push-open unit 300. , and includes a second receiving portion 120 in which the second guide rod 121 is formed. The first accommodating part 110 and the second accommodating part 120 are formed parallel to each other and can accommodate the closing unit 200 and the push-open unit 300, respectively.

The first guide rod 111 is provided in the first receiving portion 110, and includes a first straight path 111a formed long along the longitudinal direction of the housing 100, and an end of the first straight path 111a. It includes a first ramp 111b that is bent in the area. In the fully open state, the first slider 210 is rotated downward and fixed on the first ramp 111b. Thereafter, when the external activator 10 is introduced, the first slider 210 engages with the external activator 10 and rotates upward to become movable along the first straight path 111a. That is, the first straight path 111a and the first ramp 111b serve to guide the movement of the first slider 210.

The second guide rod 121 is provided in the second receiving portion 120, and includes a second straight path 121a formed long along the longitudinal direction of the housing 100, and an end of the second straight path 121a. It includes a second ramp 121b that is bent in the area. In the fully open state, the second slider 310 is rotated downward and fixed on the second ramp 121b. Thereafter, when the external activator 10 is introduced, the second slider 310 engages with the external activator 10 and rotates upward to become movable along the second straight path 121a. That is, the second straight path 121a and the second ramp 121b serve to guide the movement of the second slider 310.

That is, the external activator 10 is first coupled to the second slider 310 of the push-open unit 300 and rotates the second slider 310 upward. Next, the external activator 10 is connected to the first slider 210 of the closing unit 200 after being drawn in for a certain period and rotates the first slider 210 upward. Accordingly, the external activator 10 moves in the closing direction while being coupled to both the first slider 210 and the second slider 310.

Meanwhile, a third guide rod 122 may be further provided in the second receiving portion 120. The third guide rod 122 is provided on the same line as the second guide rod 121 and on a closed direction side than the second guide rod 121. The third guide rod 122 includes a third straight path 122a formed long along the longitudinal direction of the housing 100, and a third ramp 122b formed by bending at an end region of the third straight path 122a. Includes. When the third guide rod 122 forcibly withdraws the external activator 10 in the retracted state, the second slider 310 is rotated downward by the third ramp 122b so that the external activator 10 moves toward the second slider. So that it can be separated from (310).

Figure 5 is a perspective view of a closing unit according to an embodiment of the present invention, and Figure 6 is an exploded view of a closing unit according to an embodiment of the present invention.

Referring to FIGS. 5 and 6 , the closing unit 200 includes a first slider 210, a damper 220, and a first elastic member 230.

The first slider 210 engages with the external activator 10 when retracted, and is guided by the first straight path 111a and the first ramp 111b of the first guide rod 111 and moves in the closing direction.

Meanwhile, the first slider 210 includes a first coupling part 211, a first separation prevention part 212, a damper connection part 213, and a first elastic member connection part 214. More specifically, the first slider 210 has a first coupling portion 211 that is recessed and is engaged or released from the external activator 10, and a first separation prevention portion formed on the front side of the first coupling portion 211. (212), a damper connection part 213 to which one end of the damper rod 222 is connected, and a first elastic member connection part 214 to which one end of the first elastic member 230 is connected.

The first coupling portion 211 is recessed downward and serves to move the first slider 210 in the open direction or in the closed direction by engaging or disengaging from the external activator 10.

The first separation prevention portion 212 is configured to prevent the external activator 10 from being separated and is formed on the front side of the first coupling portion 211. However, when the external activator 10 is withdrawn, the first slider 210 is rotated downward by the first guide rod 111, and thereby the external activator 10 can be separated from the first coupling portion 211. there is.

The damper 220 includes a damper body 221, a damper rod 222, and a mounting portion 223.

More specifically, the damper 220 includes a damper body 221 inserted into and coupled to the damper receiving portion 112, a damper rod 222 provided to be movable in the longitudinal direction from the damper body 221, and the damper rod. It is formed at the end of 222 and includes a mounting portion 223 mounted on the first slider 210.

That is, the damper 220 provides a buffering force when the first slider 210 is retracted, and soft closing can be performed by the buffering force.

The first elastic member 230 is provided to connect the housing 100 and the first slider 210, and this first elastic member 700 is elastically compressed or stretched when the external activator 10 moves. According to one embodiment, the first elastic member 230 may be a tension spring.

More specifically, when the first slider 210 moves in the closing direction due to the introduction of the external activator 10, the first elastic member 230 pulls the first slider 210 in the closing direction and performs a closing operation. . On the other hand, when the first slider 210 moves in the opening direction according to the withdrawal of the external activator 10, the first elastic member 230 is gradually tensioned. That is, self-closing can be performed by the elastic restoring force of the first elastic member 230 in the closing direction.

In this way, the closing unit 200 performs a self-closing function by the first elastic member 230 and a soft closing function by the damper 220 to enable smooth introduction of the external activator 10.

Figure 7 is a plan view and a perspective view of a push-open unit according to an embodiment of the present invention, Figure 8 is an exploded view of a push-open unit according to an embodiment of the present invention, and Figure 9 is a rotator according to an embodiment of the present invention. , and Figure 10 shows a moving carriage according to an embodiment of the present invention.

7 to 10, the push-open unit 300 includes a second slider 310, a second elastic member 350, and a locking mechanism.

More specifically, the push-open unit 300 includes a second slider 310 that moves along the second guide rod 121 and engages with the external activator 10, and moves the second slider 310 in the opening direction. It is configured to include a second elastic member 350 and a locking mechanism that locks or unlocks the contraction of the second elastic member 350 as the external activator 10 is introduced.

The second slider 310 engages with the external activator 10 when retracted, and is guided by the second straight path 121a and the second ramp 121b of the second guide rod 121 and moves in the closing direction.

Meanwhile, the second slider 310 includes a second coupling portion 311, a second separation prevention portion 312, and a carriage connection portion 313. More specifically, the second slider 310 has a second coupling portion 311 that is recessed and is engaged or released from the external activator 10, and a second separation prevention portion formed on the front side of the second coupling portion 311. It is configured to include (312) and a carriage connection portion (313) connected to one side of the moving carriage (320).

The second coupling portion 311 is recessed downward and serves to move the second slider 310 in the open direction or in the closed direction by engaging or disengaging from the external activator 10.

The second separation prevention portion 312 is configured to prevent the external activator 10 from being separated and is formed on the front side of the second coupling portion 311. However, when the external activator 10 is withdrawn, the second slider 310 is rotated downward by the second guide rod 121, and thereby the external activator 10 can be separated from the second coupling portion 311. there is. Alternatively, when the external activator 10 is forcibly withdrawn, the second slider 310 is rotated downward by the third guide rod 122, and thereby the external activator 10 is forcibly separated from the second coupling portion 311. It can be.

The second elastic member 350 is provided to connect the housing 100 and the second slider 310, and the second elastic member 350 is elastically compressed or stretched when the external activator 10 moves. According to one embodiment, the second elastic member 350 may be a compression spring.

More specifically, when the second slider 310 moves in the closed direction due to the introduction of the external activator 10, the second elastic member 350 pushes the second slider 310 in the open direction. The external activator 10 is first coupled to the second slider 310 when introduced, and is positioned at a position where it can be coupled to the first slider 210 when an external force greater than the elastic force of the second elastic member 350 is applied. It can be entered up to.

When the external activator 10 is coupled to the first slider 210 and the second slider 310 by an external force greater than the elastic force of the second elastic member 350, the second elastic member 350 is locked by a locking mechanism. Since the contraction is locked, the elastic force of the second elastic member 350 does not act, and the device moves in the closing direction only by the elastic force of the first elastic member 230. This locking mechanism may be performed by the interaction of the shaft 330 and the rotator 340, as will be described later.

Meanwhile, the push-open unit 300 further includes a moving carriage 320, a shaft 330, a rotator 340, and a support member 360.

The shaft 330 is fixed at both ends to the shaft fixing part 123 formed in the second receiving part 120, and includes one or more operating protrusions 331 and one or more stopping protrusions 332.

More specifically, the shaft 330 includes one or more operating protrusions 331 protruding from the outer peripheral surface, and one or more locking protrusions 332 protruding from the outer peripheral surface at positions spaced apart from the operating protrusions 331 at a predetermined distance. do.

The operating protrusions 331 engage with the rotator 340 to induce rotation in one direction of the rotator 340, and are formed at least two or more along the circumference of the outer peripheral surface of the shaft 330. In addition, the locking protrusion 332 is configured to repeat locking and unlocking with respect to the rotator 340, and is formed at least two or more on the outer peripheral surface at a certain distance from the operating protrusion 310 of the shaft 330. .

One side of the moving carriage 320 is coupled to the second slider 310 and moves together with the second slider 310, and the shaft 330 is inserted through it to move in the longitudinal direction along the shaft 330. .

The moving carriage 320 includes a locking portion 321 and a guide portion 322.

The locking portion 321 is formed on the inner peripheral surface of the moving carriage 320. More specifically, the locking portion 321 catches the outer protrusion 343 of the rotator 340 when the external activator 10 is retracted so that the rotator 340 can be retracted together for a certain period.

The guide portion 322 is formed on the inner peripheral surface of the moving carriage 320. More specifically, when the external activator 10 is introduced, the guide unit 322 rotates in one direction by the operating protrusion 331 of the shaft 330 and the outer protrusion 343 is released. , which guides the relative movement of the rotator 340 into the interior of the moving carriage 320.

The rotator 340 engages with the moving carriage 320 for a certain period and moves together in the closing direction. Additionally, the rotator 340 is inserted through the shaft 330 and moves along the shaft 330. When the rotator 340 is retracted, it is rotated in one direction by the operating protrusion 331 of the shaft 330, and locking or unlocking with the locking protrusion 332 of the shaft 330 is repeated according to the retracting operation.

Meanwhile, the rotator 340 includes a ratchet protrusion 341, a passage portion 342, and an outer protrusion 343 on the inner peripheral surface.

More specifically, the rotator 340 includes one or more ratchet protrusions 341 on the inner peripheral surface and one or more passage portions 342 formed between the ratchet protrusions 341. At this time, it is preferable that at least two ratchet protrusions 341 are provided radially on the inner peripheral surface of the rotator 340.

The ratchet protrusion 341 may be formed in an “H” shape and engages with the operating protrusion 331 to induce rotation of the rotator 340, and engages with the stopping protrusion 332 to prevent movement of the rotator 340 in the withdrawal direction. Performs a locking role. The passage portion 342 is formed between the ratchet protrusions 341 and serves as a passage to prevent the lock from being caught by the catching protrusion 332 when the lock is unlocked.

The ratchet protrusion 341 includes a first ratchet protrusion 341a, a second ratchet protrusion 341b, and a blocking protrusion 341c.

The first ratchet protrusion (341a) is formed in an inclined plane shape at both ends, and one end engages with the operating protrusion (331) and the other end engages with the stopping protrusion (332). The second ratchet protrusion (341b) is arranged in parallel with the first ratchet protrusion (341a), has both ends formed in an inclined plane shape, one end engages with the operating protrusion 331, and the other end engages with the stopping protrusion 332. The blocking protrusion 341c connects the first ratchet protrusion 341a and the second ratchet protrusion 341b, and is caught by the blocking protrusion 332 when locked, blocking movement in the opening direction.

At this time, one end of the operating protrusion 331 is formed to correspond to the inclined surface shape of the first ratchet protrusion 341a and the second ratchet protrusion 341b, and one end of the stopping protrusion 332 is formed to correspond to the first ratchet protrusion (341a). 341a) and may be formed to correspond to the inclined plane shapes of the second ratchet protrusion 341b. That is, the operating protrusion 331, the stopping protrusion 332, the first ratchet protrusion 341a, and the second ratchet protrusion 341b are configured so that each end has an inclined surface formed at the same angle. As a result, the rotational movement distance of the rotator 340 becomes the same during locking and unlocking operations, thereby preventing malfunction between each part.

Meanwhile, the support member 360 is inserted through the shaft 330 and moves along the shaft 330, and is connected to one end of the second elastic member 350. The support member 360 is located on the inlet side of the rotator 320 and supports the operation of the second elastic member 350 as the rotator 320 moves. That is, the second elastic member 350 is compressed or expanded while one end is connected to the support member 360.

Figure 11 shows the operation process when closing the slide module according to an embodiment of the present invention.

Referring to FIG. 11, the operation process when the slide module 1000 is closed will be described. The closed section is divided into a lead-in section (A) and a self-closing section (B).

(1) In the lead-in section (A), the external activator 10 is first coupled to the second slider 310 of the push-open unit 300 by an external force, and then the first slider 210 of the closing unit 200 It moves until it is combined with. At this time, the outer protrusion 343 of the rotator 340 is caught in the locking portion 321 of the movable carriage 320, and the rotator 340 and the movable carriage 320 move together in the closing direction.

(2) In the self-closing section (B), when the external activator 10 is coupled with the first slider 210, self-closing by the first elastic member 230 begins. At this time, the rotator 340 rotates in one direction by the operating protrusion 331 of the shaft 330 to release the lock on the outer protrusion 343, and the rotator 340 moves relative to the inside of the moving carriage 320. becomes possible. Additionally, as the rotator 340 rotates in one direction, it is locked to the locking protrusion 332 of the shaft 330 and movement in the opening direction is blocked. That is, the operation of the second elastic member is locked by a locking mechanism based on the interaction between the shaft 330 and the rotator 340. Thereafter, self-closing and soft closing are performed while the external activator 10 is coupled to the first slider 210 and the second slider 310.

Figure 12 shows an operating process when opening a slide module according to an embodiment of the present invention, and Figure 13 shows a locking mechanism according to an embodiment of the present invention.

With reference to FIGS. 12 and 13 , the operation process when opening the slide module 1000 will be described. The open section is divided into a push section (C) and an open section (D).

(1) In the push section C, when the external activator 10 is pushed a certain distance by an external force, the second elastic member 350 is unlocked and becomes movable in the opening direction. More specifically, when the external activator 10 is pushed a certain distance by an external force in the retracted state, it is retracted a certain distance into the rotator 340 by the pressure of the moving carriage 320, and at this time, the rotator 340 moves the operating protrusion 331. ) and rotates. When the rotator 340 is rotated by the operating protrusion 331 of the shaft 330, the blocking protrusion 332 of the rotator 340 is not blocked by the blocking protrusion 332 of the shaft 330, that is, the lock is unlocked. It becomes a state in which movement in the opening direction is possible due to the elastic force of the second elastic member 350.

(2) In the open section (D), the external activator 10 is coupled to the first slider 210 and the second slider 310 and moves in the opening direction by the elastic force of the second elastic member 350. do.

Figure 14 shows the operation process when forcibly withdrawing the slide module according to an embodiment of the present invention.

Referring to FIG. 14, when the external activator 10 is forcibly withdrawn by an external force in the retracted state, the second slider 310 rotates downward by the third ramp 122b of the third guide rod 122. Accordingly, the external activator 10 is in a state in which it can be separated from the second coupling portion 311. If external force continues to be applied, the external activator 10 is pulled out in a state coupled to the first slider 210, so that the slide module 1000 can only use the self-closing and soft closing functions by the closing unit 200. It becomes a state.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as unitary may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the patent claims described below, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention.

1000 slide module
100 housing
110 first receptacle
120 second receiving part
200 closing units
210 1st slider
220 damper
230 First elastic member
300 push open unit
310 2nd slider
320 moving carriage
330 shaft
340 rotator
350 second elastic member
360 support member

Claims (9)

A housing including a first accommodating part in which a first guide rod is formed and a second accommodating part in which a second guide rod is formed;
It has a first slider that moves along the first guide rod and engages with an external activator, a first elastic member that moves the first slider in a closing direction, and a damper that buffers the movement of the first slider, 1 Closing unit accommodated in the receiving portion; and
A second slider that moves along the second guide rod and engages with the external activator, a second elastic member that moves the second slider in an opening direction, and operation of the second elastic member as the external activator is introduced. comprising a push-open unit having a locking mechanism to lock or unlock,
When closed, the closing unit is operated by the external activator to perform a self-closing function, and when opened, the push-open unit is unlocked and pushed when pressed by a push operation while the external activator is inserted. Performs a push-open function,
The closing unit accommodated in the first accommodating portion and the push-open unit accommodated in the second accommodating portion are arranged in parallel and include at least a portion of a section operated together by the external activator. According to paragraph 1,
The closed section is divided into a lead-in section (A) and a self-closing section (B),
In the lead-in section (A), the external activator is first coupled with the second slider by an external force and then moves until it is coupled with the first slider,
In the self-closing section (B), the external activator is coupled to the first slider and the second slider and moves in the closing direction by the elastic force of the first elastic member. According to paragraph 2,
The open section is divided into a push section (C) and an open section (D),
In the push section (C), when the external activator is pushed a certain distance by an external force, the second elastic member is unlocked and can move in the opening direction,
In the open section (D), the external activator is coupled to the first slider and the second slider and moves in the opening direction by the elastic force of the second elastic member. According to paragraph 3,
The push open unit is,
A shaft having one or more operating protrusions protruding from the outer peripheral surface and one or more locking protrusions protruding from the outer peripheral surface at a predetermined distance from the operating protrusions, and fixedly installed in the housing;
a movable carriage on one side of which is coupled to the second slider and through which the shaft is inserted and moves along the shaft;
A rotator that engages with the moving carriage for a certain section and is retracted together, the shaft is inserted through and moves along the shaft, and when retracted, rotates in one direction by the operating protrusion, thereby repeatedly locking or unlocking with the locking protrusion. ; and
The shaft is inserted through and moves along the shaft, is connected to one end of the second elastic member, and further includes a support member that supports the operation of the second elastic member according to the movement of the rotator. , slide module. According to clause 4,
The rotator is,
One or more ratchet protrusions formed on the inner peripheral surface; and
A slide module, characterized in that it includes one or more passages formed between the ratchet protrusions. According to clause 5,
The ratchet protrusion,
a first ratchet protrusion having both ends formed in an inclined plane shape and engaging with the operating protrusion and the locking protrusion;
a second ratchet protrusion disposed parallel to the first ratchet protrusion, both ends of which are formed in an inclined plane shape, and engaged with the operating protrusion and the locking protrusion; and
A slide module comprising a blocking protrusion that connects the first ratchet protrusion and the second ratchet protrusion and is configured to engage the locking protrusion when locked. According to clause 6,
One end of the operating protrusion is formed to correspond to the inclined surface shape of the first ratchet protrusion and the second ratchet protrusion,
A slide module, characterized in that one end of the stopping protrusion is formed to correspond to the inclined surface shape of the first ratchet protrusion and the second ratchet protrusion. According to paragraph 4,
The rotator is,
It includes a plurality of outer protrusions formed in a circular shape on the outer peripheral surface,
The moving carriage,
A locking portion formed on the inner peripheral surface that catches the outer protrusion in the inlet section (A) to allow the rotator to be retracted together, and a locking portion formed on the inner peripheral surface that rotates in one direction and releases the locking portion in the self-closing section (B). ) includes a guide portion that guides the relative movement of the rotator inward,
A slide module, characterized in that the rotator is rotated by the operating protrusion when moving from the lead-in section (A) to the self-closing section (B). According to paragraph 4,
A slide module, characterized in that the locking mechanism is performed by interaction of the shaft and the rotator.