KR101056875B1 - Rack and pinion assembly with alignment - Google Patents

Abstract

The present invention relates to a rack and a pinion assembly in which alignment means are formed so that the left and right sides of the drawer are aligned and drawn in when the drawer is overtraveled and drawn out.

The alignment means comprises a horizontal alignment portion formed parallel to the gear portion of the rack at the end of the rack body in the drawing direction, and a plate-like alignment portion formed on the side opposite to the side on which the pinion portion is formed. At this time, the gear teeth of the rack are not formed at a position corresponding to the horizontal portion of the horizontal alignment portion, the gear teeth start from a position corresponding to one side of the horizontal portion of the horizontal alignment portion.

Drawers, Overtravel, Rack and Pinion Assemblies, Aligners

Description

Rack and pinion assembly having aligning means

The present invention relates to a rack and pinion assembly having alignment means, and more particularly, to a rack and pinion assembly in which alignment means are formed so that the left and right sides of the drawer are aligned and drawn in when the drawer is overtraveled after the drawer is drawn out.

When the slide is attached to both sides of the drawer and used, the slides attached to the left and right sides of the drawer are not always drawn out and drawn in at the same speed. If the left and right slides are not drawn out or drawn in at the same speed, the drawer is drawn out twisted to either the left or the right side. This causes inconvenience to the user, and the load according to the drawer and its contents may exert a compressive force on one side of the slide and a tension force on the other side, thereby causing an abnormality in the operation of the slide.

Rack and pinion assemblies are devices that allow slides attached to the left and right sides of a drawer to be always withdrawn and drawn at the same speed. The pinion assembly typically has a rack having a gear tooth formed on one side of a straight body and a disc shape, and is composed of a pinion having gear teeth engaged with the gear tooth of the rack at the circumference of the disc. Attaching the rack and the pinion assembly to the slides prevents the pins from being drawn out or pulled in as the pinion always moves regularly along the rack. Since the slides are installed on the left and right sides of the drawer, the rack and pinion assemblies must also be attached to the left and right slides. Known techniques for racks and pinion assemblies used to draw and retract the left and right slides at the same speed include US Patent Publication No. 2005 / 0160854A1 and Korean Patent Application No. 10-2007-0075609 by the present applicant.

In some drawers, the back wall of the drawer is configured to allow overtravel, withdrawal beyond the end of the body, such as a desk. Figure 1 shows a perspective view of an overtraveled drawer (overtravel distance L), in order for the drawer 2 to be able to overtravel past the body 1, the slide 5 must be a three-fold fold type. .

Even in the case of a drawer capable of overtraveling, the rack and pinion assembly may be attached and used so that the left and right slides are drawn out and drawn in at the same speed. 2 and 3 are perspective views of a slide to which a conventional rack and pinion assembly is attached, and FIG. 2 shows a state in which the slide 5 is fully retracted, and FIG. 3 shows the slide 5 fully retracted and overtraveled. Show status

2 and 3, the drawer is omitted for convenience, but the drawer is located between the left and right slides 5, and the movable rails 6 (outside of the inner and outer movable rails) Then, the movable rail refers to this outer movable rail) is attached to the side wall of the drawer and the fixed rail 7 is attached to the inner wall of the main body such as a desk. Accordingly, when the drawer is pulled out, the moving rail 6 of the slide is pulled out and pulled out. The rack 10 of the rack and pinion assembly is installed at one side of the fixed rail 7 and the pinion 12 is attached to one end of the movable rail 6 to perform a rolling motion along the rack 10. The attachment of the pinion 12 to the movable rail 6 is through the binding hole 14 of a suitable configuration, in which one side binds to the movable rail 6 and the other side binds to one side of the pinion 12. The pinion 12 on the left and right sides is connected by a connecting rod 16 (located outside the rear wall of the drawer) to perform a rolling motion along each rack 10. Therefore, when the drawer draws in and out, the moving rails 6 of the left and right slides attached to the drawer perform the drawing and pulling movement, but the pinion 12 attached to the moving rails 6 follows the rack 10. Since the rolling motion is performed at a constant speed, the left and right slides are withdrawn and withdrawn at the same speed. As a result, the drawers are withdrawn and withdrawn without twisting the left and right sides.

In the case of a slide with a conventional rack and pinion assembly, when the drawer is overtraveled, the pinion 12 is disengaged from the rack 10 (see FIG. 3). When the drawer is pulled out after overtravel withdrawal, it may occur that the pinions 12 on the left and right sides are engaged with the rack 10 so as to be offset from each other (not horizontally). That is, since the user does not always draw or draw by applying left and right symmetrical force to the center of the drawer, when the user applies a force deflected to the left or right of the drawer to the drawer, the pinion of either the left or right drawer Since the 12 is engaged with the rack 10 first, the pinions on the left and right sides are shifted from each other. If the deviation is more than 1 pitch (distance corresponding to one rack or pinion gear), the drawer is retracted while the left and right pinion misalignment remains, and the drawer is left and right in the final retracted state. It will be left off from this body. Therefore, there is an inconvenience that the user should always draw the drawer with care so that the above does not occur when the overtravel in and out is introduced.

An object of the present invention is to allow the left and right sides of the drawer to be pulled in and out without twisting to either side.

Another object of the present invention is to allow the drawer to be drawn without twisting to either side even when the drawer is withdrawn after overtravel withdrawal.

In order to achieve the above object, the present invention aligns the left and right side of the drawer when the drawer is overtravel withdrawn after the drawer is attached to the rack and pinion assembly attached to the slide so that the left and right slides are always withdrawn and drawn at the same speed. It provides an alignment means to be pulled in.

In the case of the rack and pinion assembly according to the present invention, as in the prior art, the rack is attached to one side of the slide fixing rail, the elongated body and a gear tooth formed in the longitudinal direction on one side of the moving body. The pinion is attached to the slide moving rail and has a disc shape. The circumferential portion of the pinion disc is formed with gear teeth engaged with the gear teeth of the rack, and on one side of the disc has a fixing portion for engaging the binding hole for binding the pinion to the moving rail of the slide.

The alignment means according to the present invention comprises a horizontal alignment portion formed in parallel with the gear portion of the rack at the end of the rack body in the drawing direction, and a plate-like alignment portion formed on the side of the pinion. The plate-like alignment of the pinion is formed on the side opposite to the side on which the fixing portion is formed. The gears of the rack are not formed at a position corresponding to the horizontal portion of the horizontal alignment portion and the gear teeth start from a position corresponding to one side of the horizontal portion of the horizontal alignment portion. In addition, the gear portion of the rack at a position corresponding to one side of the horizontal portion of the horizontal alignment portion and the gear portion of the pinion which meets the plate-alignment extension line of the pinion are aligned with each other when the pinion performs normal rolling motion along the rack. The physics is configured to correspond to the gear tooth of the rack and the gear tooth of the pinion. By such alignment means, the drawer may be drawn without twisting to either side even when the drawer is withdrawn after overtravel withdrawal.

In the rack and pinion assembly according to the present invention, the pinion is fixed to the slide moving rail and attached to the slide moving rail via a connecting plate moving along the moving rail. That is, a circular groove is formed in the connecting plate, and the pinion fastener is attached around the groove, and the pinion is coupled to the pinion fastener so that the pinion is attached to the moving rail.

A hollow protrusion is formed at the center of the binding port. The fixing part of the pinion is composed of a circular protrusion having a groove formed therein and an elastic plate positioned along the outer periphery of the circular protrusion. Connecting grooves connecting the pinions of the left and right are inserted into the grooves formed in the circular protrusions. At one end of the elastic plate, a fixing projection having a triangular cross section is formed, so that it is easily inserted when the fixing portion of the pinion is inserted into the hollow portion of the hollow projection of the binding hole, but once inserted, the fixing projection of the elastic plate is hollow. By binding to the projections, the pinion is prevented from being separated from the binding port. In this way, the pinion and the binding port simply combine the pinion fixing part by inserting the pinion into the hollow projection of the binding port.

It is preferable that a receiving groove into which the elastic plate is inserted is formed on the outer peripheral surface of the pinion when the elastic plate binds to the hollow projection.

A rectangular slide housing having a bottom surface to which the slide is fixed and having a ceiling surface and one side open to facilitate slide installation. The rack of the rack and pinion assembly according to the present invention can also be applied to the slide housing by forming a rack on one side of the slide housing. As described above, in the case where the rack is formed on one side of the slide housing, the connecting plate, which serves as a medium for attaching the pinion to the slide moving rail, has a guide flange which is engaged with one longitudinal side of the slide housing on one side thereof and moves along it. It is preferably formed.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention;

Rack and pinion constituting the rack and pinion assembly according to the present invention, as shown in Figures 5 to 7, the basic configuration is the same as the conventional rack and pinion. More specifically, the rack 20 according to the present invention includes an elongated body 21 and a plurality of gear teeth 22 formed in a longitudinal direction along one side of the body as in the prior art, and the pinion ( 30 is a disc shape, a gear tooth 32 that is engaged with the gear teeth 22 of the rack 20 is formed on the circumference of the disc.

On the other hand, the rack and pinion assembly according to the present invention, unlike the prior art when the drawer is drawn over the left and right sides of the drawer when the drawer is arranged alignment means to be inserted.

As the alignment means, the pinion 30 is provided with a plate-like alignment portion 34. The plate-like alignment portion 34 is formed on one side of the plate of the pinion 30, that is, the side opposite to the side on which the pinion portion 40 of the pinion is formed. As shown in Fig. 6, the plate-like alignment portion 34 is formed in a protruding plate state having a predetermined length, and is formed along a straight line (diameter of the disc) across the center of the disc.

In the rack 20, horizontal alignment portions 24 are formed at one end of the rack body (ends in the direction corresponding to the extraction direction when the rack is installed) as the alignment means. The horizontal alignment part 24 is formed parallel to and spaced apart from the rack body part, that is, the gear tooth part of the rack, in which the gear teeth 22 of the rack are formed. The horizontal alignment portion 24 has a horizontal portion 26 having a predetermined length horizontally formed with the gear teeth 22 of the rack, and the connecting portion 27 formed at an appropriate shape and angle is positioned on both sides of the horizontal portion 26. do. The height H of the horizontal portion 26 is the pinion described above when the gear teeth 32 of the pinion 30 mesh with the gear teeth 22 of the rack 20 and make a rolling motion along the rack 20. It is in contact with the bottom of the plate-like alignment portion 34 of the ON to maintain a slightly smaller than this. That is, the height H from the lowest gear teeth 22 of the rack to the horizontal portion 26 is elastically aligned from the length R from the center O of the pinion disc to the highest point of the pinion gear teeth 32. It is slightly smaller than the distance minus 1/2 of the thickness of the part 34 (see Fig. 10).

The horizontal alignment portion 34 of the rack and the plate-like alignment portion 34 of the pinion interact with each other so that the left and right sides of the drawer are aligned when the drawer is pulled out after the overtravel withdrawal of the drawer, which will be described later.

In the rack 20 according to the present invention, a gear tooth is not formed in the gear tooth portion 28 at a position corresponding to (corresponding to) the horizontal portion 26 of the horizontal alignment portion 24 among the gear teeth of the rack 20. . The length of the gear teeth 28 in which this gear tooth is not formed may have any length, but is preferably larger than the overtravel length L of the drawer described with reference to FIG.

The fixed rail of the slide and the rack 20 themselves slide so that the drawer of the desk overtravels (overtravel length L) upon maximum withdrawal of the movable rail of the slide without protruding beyond the end of the body (e.g. desk). And racks are properly positioned and installed on desks and drawers. In this state, when the drawer is in the maximum withdrawal position to be overtraveled and drawn out, the pinion 30 has a gear tooth portion 28, in which a gear tooth is not formed, more specifically, an end portion of the gear tooth portion 28 in the drawing direction. You will be closer to.

 The gear tooth 22 of the rack 20 is not formed at a position corresponding to the horizontal portion 26 of the horizontal alignment portion, but one side of the horizontal portion 26 of the horizontal alignment portion (inside the horizontal portion corresponding to the retraction direction when the rack is installed). The gear tooth 22 starts from the position corresponding to (the position of the dotted line A in Fig. 10). At this time, the gear teeth 22 portion of the rack that meets the gear teeth 22 portion of the rack at the position corresponding to one side of the horizontal portion 26 of the horizontal alignment portion and the extension line of the plate-aligned portion 34 of the pinion is pinion ( 30 is configured to correspond to the gear teeth 22 portion of the rack and the gear teeth 32 portion of the pinion engaged with each other when the normal rolling motion along the rack 20. In the illustrated embodiment, the gear teeth 22 portion of the rack at a position corresponding to one side of the horizontal portion 26 of the horizontal alignment portion is the lowest point of the rack gear teeth, and the pinion is formed to be the highest point of the pinion gear teeth. It is easy to form as in the embodiment, but even if formed differently, as described above, these parts are gear teeth 22 of the rack meshing with each other when the pinion 30 makes a normal rolling motion along the rack 20. The rack and pinion should be configured to correspond to the gear teeth 32 of the part and pinion so that the rack and pinion will be smoothly rolling.

As shown in FIG. 4, the rack 20 is attached to one side of the fixed rail 6 ′ of the slide 5 ′ as in the prior art, and the pinion 30 is attached to the slide moving rail 7 ′ with the slide 20. It is attached to the slide moving rail 7 'via a connecting plate 60 fixed to the moving rail 7' and moving along the moving rail. A circular groove 62 is formed at one side of the connecting plate 60, and the pinion fastener 50 is attached along the circumference of the circular groove 62. The insertion groove 41 of the pinion fixing portion 40 to be described later is inserted into the circular groove 62, and the outer diameter of the circular groove 62 is formed larger than the outer diameter of the pinion side plate 34 to be described later. . Fixing holes 64 and 67 through which fastening means such as screws or rivets are formed at a suitable position for fixing to the moving rail of the connecting plate and attachment to the connecting plate of the pinion fastener.

As shown in Figs. 8 and 9, the pinion fastener 50 has a rectangular plate-like body, and a hollow protrusion 52 is formed at the central portion of the plate-like body to protrude to one side. The hollow portion 54 of the hollow projection 52 is a through hole formed through the plate-like body, and the cross section of the through hole has a circular shape. An appropriate number of plate-shaped support portions 53 are formed around the outer circumferential portion of the hollow protrusion 52 to serve as a support for the opening of the hollow protrusion 52. On the other side of the plate-like body (the opposite side of the surface from which the hollow projection protrudes), a circular groove portion 56 into which the side plate 34 of the pinion to be described later is inserted is formed. In addition, the fastening hole 58 is formed at the position corresponding to the fixing hole 64 of the connecting plate for attachment to the connecting plate 60.

As described above with reference to FIGS. 6 and 7, the pinion 30 has a gear tooth 32 formed to engage with the gear teeth 22 of the rack along its outer circumference and has a plate-like alignment portion on one side thereof. 34 is formed. On the other hand, the other side of the pinion (30) is formed with a fixing portion 40 for engaging and engaging the above-described binding port (50).

In the illustrated embodiment, the pinion 30 is formed with a side disc 36 having an outer diameter equal to the outer diameter of the gear teeth 32 along one side cross-section of the gear teeth 32. Although this side plate 36 is arbitrary structure, it is preferable to be formed. The side plate 36 serves as a support for supporting the gear teeth 32. In addition, when the pinion 30 is coupled to the binding port 50, the pinion 30 is easily connected to the binding port 50 by inserting the side plate 36 into the circular groove 56 of the binding port described above. It is located in the binding position.

The pinion fixing portion 40 is composed of a circular protrusion 41 and an elastic plate 44 positioned along the outer peripheral portion of the circular protrusion. In the center of the circular protrusion 41, a groove 42 having a suitable shape is formed inwardly, and the groove 42 connects the pinion of the left and right sides and is formed in a shape corresponding to the shape of the groove 42. 80 (see Fig. 4) is inserted.

The elastic plate 44 is formed at equal intervals along the circumference of the circular protrusion 41 in at least two or more numbers, and in the illustrated embodiment, four elastic plates are formed at 90 ° intervals. Each elastic plate 44 is located slightly spaced from the circular protrusion 41 in the form of an elongated plate. A fixing protrusion 45 is formed at one end of the elastic plate. The fixing protrusion 45 has a triangular cross section so that the fixing protrusion 40 of the pinion can be easily inserted into the hollow portion of the hollow protrusion 52 of the binding port, but once inserted, the fixing protrusion of the elastic plate By binding the 45 to the hollow projection 52, the pinion 30 is prevented from being separated from the binding port 50. On the other hand, it is preferable that the receiving groove 43 into which the elastic plate 44 is inserted is formed on the outer circumferential surface of the circular protrusion 41 of the pinion when the elastic plate 44 is bound to the hollow protrusion 52. The groove 46 formed in the pinion body of the elastic plate 44 is for forming an extension of a mold for forming the elastic plate 44 when the pinion 30 is injection molded into plastic.

When the fastener 50 and the pinion fixing part 40 are configured as described above, the pinion 30 can be simply inserted into the hollow projection 52 of the fastener by inserting the pinion fixing part 40 of the pinion into the hollow projection 52. ) Is coupled to the binding port (50). The pinion 30 should be rotated in the state coupled with the binding port (50). Therefore, the diameter of the hollow portion 54 of the hollow projection 52 of the binding port, the outer diameter of the circular projection 41 of the pinion, the thickness of the elastic plate 44, the depth of the receiving groove 43, the fixing projection 45 The dimensions of each component, such as the thickness of the appropriate to be selected so that the pinion 30 can be easily coupled to the fastener and at the same time smoothly rotational movement.

The pinion 30 couples with the fastener 50, the fastener 50 is attached to the connecting plate 60 by suitable fastening means such as screws or rivets, and the connecting plate 60 is also connected to the suitable fastening means. By being fixed to the moving rail 7 'of the slide, the pinion is attached to the moving rail via the connecting plate. As shown in Fig. 4, the fixed rails 6 'of the pair of slides are installed at appropriate positions on the inner surface of the desk (not shown), and the rack 20 is attached to one side of the fixed rails 6' and moved. When the rail 7 'and the connecting plate 60 are fixed at the corresponding positions of the drawer (not shown), and the pinion 30 is attached to the moving rail 7' via the connecting plate 60, The rack and assembly according to the invention are installed together with the slide 5 '. Although not shown in FIG. 4 for convenience, the drawer is located between a pair of slides 5 'and a connecting rod 80 is located outside the rear wall of the drawer so that the conventional rack and pinion assembly described with reference to FIGS. Will be in the same position as

Since the basic operation of the rack and pinion assembly according to the present invention is the same as that of the conventional rack and pinion assembly, it will not be described any more, and the operation of the alignment means, which is a main feature of the present invention, will be described with reference to FIG. . FIG. 10 is a perspective view illustrating a state in which the pinion 30 is positioned near the horizontal alignment unit 24 of the rack 20, and other parts of the rack 20 are omitted for convenience of description. In addition, the left and the right pinion is connected by the connecting rod 80 to perform the left and right symmetrical movement with each other, so only one rack and the pinion are illustrated.

As described above, when the drawer is in the overtraveled and withdrawn position, the pinion 30 is located in the gear tooth portion 28 where the gear teeth are not formed, and the pinion 30 shown in FIG. The 1 position corresponds to the position of the drawer that is overtraveled at most. When the drawer is retracted in the maximum overtraveled position, the first position of the illustrated pinion 30 is such that the plate-aligned portion 34 of the pinion 30 is positioned at the horizontal alignment portion 24 of the rack 20. The state which is not in alignment with the horizontal part 26 is shown as an example. When the drawer is retracted in this state, the plate-aligned portion 34 is horizontal unless the plate-aligned portion 34 is aligned with the horizontal portion 26 of the horizontal alignment portion 24 (ie, horizontal to each other). You will not be able to pass (26). Thus, the misaligned plate-aligned portion 34 rotates in position (ie, rotation of the pinion) until it is aligned with the horizontal portion 26 at the position where the horizontal portion 26 first meets, and once aligned, The plate-aligned portion 34 performs a sliding movement (ie, sliding of the pinion) along the horizontal portion 26 (second position in Fig. 10). Since the gear teeth 22 are not formed in the gear teeth 28, the rotation and sliding motion of the pinion proceed without any interference. Finally, when the drawer is retracted at a position where the gear teeth 32 of the pinion begin to meet with the gear teeth 22 of the rack, the gear teeth 32 of the pinion 30 are now gears of the rack 20. It is engaged with the tooth 22 (the third position in Fig. 10), the pinion on the left and the right side is symmetrical movement, so the pinion on the left and right side is engaged with the rack without shifting each other and the retracting movement. As such, according to the rack and pinion assembly according to the present invention, the drawer may be drawn without twisting to either side even when the drawer is pulled out after overtravel.

As shown in Fig. 11, the slide has a bottom surface 72 to which the slide is fixed, two long sides 71 and a short side 73, and the ceiling surface and one side 74 have an open rectangular slide housing ( 70 facilitates the slide installation. The rack of the rack and pinion assembly according to the present invention may be applied to the slide housing by forming the rack 20 on one side of the slide housing 70, in the case of the illustrated embodiment, the lower side 71.

Thus, in the case where the rack is formed on one side of the slide housing 70, as shown in Figure 12, the connecting plate 60 that serves as a medium for attaching the pinion to the slide moving rail slide housing on one side Preferably, a guide flange 66 is formed that engages and moves along one longitudinal side of the 70, i.e., the upper side 71. As shown in FIG.

Although the present invention has been described with reference to the accompanying drawings, the present invention is not limited thereto, and it will be apparent to those skilled in the art that various modifications may be made without departing from the scope of the following claims.

For example, the connecting plate can be variously changed in shape or size within the range that serves as described above. In addition, the rack may not be formed to face the lower side of the body, but may be formed to face upward.

1 is a perspective view of an overtraveled drawer.

Figure 2 is a perspective view showing that the slide with the conventional rack and pinion assembly is in the retracted state.

3 is a perspective view showing a state in which the slide shown in FIG. 2 is overtraveled.

4 is a perspective view of a slide to which a rack and pinion assembly is attached in accordance with the present invention.

5 is a perspective view of a rack used in the rack and pinion assembly shown in FIG.

6 and 7 are front and rear perspective views of the pinion used in the rack and pinion assembly shown in FIG.

8 and 9 are front and rear perspective views of the fastener according to the present invention.

10 is an explanatory view of an operation state of the alignment means of the rack and pinion assembly according to the present invention.

11 is a perspective view showing that a rack is formed in a slide housing.

Fig. 12 is a perspective view of a connecting plate used in the case where the rack is formed in the slide housing.

Claims (10)

A rack and pinion assembly for attaching a slide moving rail on a left and right side to a drawer and a drawer at the same speed at all times when a slide consisting of a fixed rail and a moving rail is installed and used on the left and right sides of a drawer, The rack attached to one side of the slide fixing rail includes an elongated body and a gear formed longitudinally on one side of the moving body. The pinion attached to the slide moving rail has a disc shape, and the gear of the rack is located at the circumference of the disc. In the rack and pinion assembly having a gear tooth is formed to be engaged and having a fixing portion for engaging the pinion to the moving rail of the slide on one side of the disc, Rack and pinion assembly having an alignment means characterized in that the left and right sides of the drawer to align and pull in the drawer after the overtravel withdrawal of the drawer. The rack according to claim 1, wherein the alignment means comprises a horizontal alignment portion formed parallel to the gear portion of the rack at the end of the rack body in the drawing direction and a plate-like alignment portion formed on a side opposite to the side on which the pinion portion is formed. Rack and pinion assembly having an alignment means characterized in that. 3. The rack and pinion according to claim 2, wherein gear teeth of the rack are not formed at positions corresponding to the horizontal portions of the horizontal alignment portion, and gear teeth start from positions corresponding to one side of the horizontal portion of the horizontal alignment portion. Assembly 4. The gear of claim 3, wherein the gear of the rack at a position corresponding to one side of the horizontal portion of the horizontal alignment portion and the pinion of the pinion that meets the plate-aligned extension of the pinion, the pinion is subjected to normal rolling motion along the rack. Rack and pinion assembly having alignment means characterized in that the gear portion of the rack and the gear portion of the pinion is engaged with each other. The pinion is attached to the slide moving rail via a connecting plate fixed to the slide moving rail and moving along the moving rail, wherein the connecting plate is formed with a circular groove. And a pinion fastener is attached around the groove, and the pinion fastener is coupled to the pinion fastener so that the pinion is attached to the moving rail. The method of claim 5, wherein the hollow projection is formed in the center of the binding hole, the fixing portion of the pinion is composed of a circular protrusion formed with a groove therein and an elastic plate which is located along the outer periphery of the circular protrusion, the cross section at one end of the elastic plate This triangular fixing projection is formed, so that the pinion is easily inserted when the fixing portion of the pinion is inserted into the hollow portion of the hollow projection of the binding port. Rack and pinion assembly having alignment means characterized in that it does not separate from the fastener. 7. The rack and pinion assembly of claim 6, wherein a receiving groove into which the elastic plate is inserted is formed on the outer circumferential surface of the pinion when the elastic plate is bound to the hollow projection. 7. The rack and pinion according to claim 6, wherein the rack and pinion assembly further comprises connecting rods for linking the left and right pinions, which are inserted into grooves formed in the circular projections of the pinion. On assembly. The rack having an alignment means according to any one of claims 1 to 4, wherein the rack has a bottom surface to which the slide is fixed, and the ceiling surface and one side are formed on one side of a rectangular slide housing which is opened. Pinion assembly. The pinion of claim 9, wherein the pinion is fixed to the slide moving rail and attached to the slide moving rail via a connecting plate moving along the moving rail, wherein the connecting plate is formed with a circular groove, and the pinion is bound around the groove. The ball is attached and the pinion is coupled to the pinion fastener so that the pinion is attached to the moving rail, and a guide flange is formed on one side of the connecting plate, which is engaged with one longitudinal side of the slide housing and moves along it. Rack and pinion assembly having an alignment means.

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