阅读说明：本技术 工作台机构 (Worktable mechanism ) 是由 中富芳春 小野寺健 铃木真司 于 2019-06-25 设计创作，主要内容包括：本发明提供一种齿隙较少,沿着进给丝杠的轴的方向的间隙较少,并且小型的工作台机构。工作台机构(10)具备进给丝杠(11)、具有内置进给丝杠的空间部(13a)的固定工作台(13)、可动工作台(15)以及齿隙吸收部(17),进给丝杠具备第1端部(11d)和第2端部(11e),并且工作台机构具备防止进给丝杠向第1端部侧的方向偏离的偏离防止部(19)、和调整从第2端部侧向第1端部的方向按压进给丝杠的按压力的按压力调整部(21),偏离防止部在第1端部侧与空间部的壁(13b)相接,按压力调整部以线接触的方式相接并按压于第2端部。(The invention provides a small table mechanism with less backlash and less clearance along the axial direction of a feed screw. The table mechanism (10) is provided with a feed screw (11), a fixed table (13) having a space (13a) in which the feed screw is built, a movable table (15), and a backlash absorbing section (17), wherein the feed screw is provided with a 1 st end section (11d) and a 2 nd end section (11e), the table mechanism is provided with a deviation preventing section (19) which prevents the feed screw from deviating in the direction of the 1 st end section side, and a pressing force adjusting section (21) which adjusts the pressing force pressing the feed screw in the direction from the 2 nd end section side to the 1 st end section side, the deviation preventing section is in contact with a wall (13b) of the space section on the 1 st end section side, and the pressing force adjusting section is in line contact with and presses the 2 nd end section.)

1. A table mechanism comprising a feed screw, a fixed table having a space portion in which the feed screw is incorporated, a movable table performing a predetermined operation in accordance with a rotational movement of the feed screw, and a backlash absorbing portion for preventing backlash in the feed screw,

the table mechanism includes:

a deviation preventing portion provided near a 1 st end portion, which is one end of the feed screw, and contacting a wall of the space portion to prevent the feed screw from deviating in a direction toward the 1 st end portion; and

and a pressing force adjusting portion having one end contacting a 2 nd end portion, which is the other end of the feed screw, and the other end fixed to a wall of the space portion, and adjusting a pressing force for pressing the feed screw in a direction from the 2 nd end portion to the 1 st end portion.

2. Table mechanism as in claim 1,

the pressing force adjusting portion is in line contact or point contact with respect to the 2 nd end portion of the feed screw.

3. Table mechanism according to claim 1 or 2,

the pressing force adjusting portion includes a columnar member, and one of a surface of the pressing force adjusting portion facing the 2 nd end portion and a surface of the 2 nd end portion facing the pressing force adjusting portion is formed in a spherical shape, and the other is formed in a concave shape having a surface contacting the spherical shape on a surface that is a tangent line.

4. Worktable mechanism as claimed in any of claims 1 to 3,

the pressing force adjusting portion includes a spherical member having a concave portion at a distal end thereof, the concave portion having a shape that contacts a surface tangent to the spherical member, and a spherical pressing member having a spherical pressure receiving portion at a distal end thereof, the spherical pressure receiving portion having a concave portion at a distal end thereof, the concave portion contacting a surface tangent to the spherical member, the spherical pressing member and the spherical pressing member sandwiching the spherical member along an axis of the feed screw.

5. Table structure as in any of the claims 1-4,

the pressing force adjusting portion includes a screw member for pressing the 2 nd end portion of the feed screw.

6. Table mechanism as in claim 5,

the pressing force adjusting portion further includes a rotating jig connecting portion to which a rotating jig for rotating the screw member is attachable and detachable.

7. Table structure as in any of the claims 1-6,

the deviation preventing portion includes a protruding portion that protrudes in a direction perpendicular to an axis of the screw shaft such that a distance between a surface of the deviation preventing portion on the 1 st end portion side and an end surface of the 1 st end portion is T or less where T is a unit of mm, where T is T when a thickness of a wall of the space portion is T.

8. Worktable mechanism as claimed in any of claims 1 to 7,

the 1 st end of the feed screw is provided with a rotary jig connecting portion to which a rotary jig for rotating the feed screw is attachable and detachable.

9. Worktable mechanism as claimed in any of claims 1 to 8,

the backlash absorbing portion includes a cylindrical resin member having a through hole of the feed screw.

10. Worktable mechanism as claimed in any of claims 1 to 9,

the backlash absorbing portion has a metal shield around it.

11. Table mechanism as in claim 9,

the resin member is composed of at least one of an amide resin, a urethane resin, and a rubber resin.

Technical Field

The present invention relates to a small table mechanism including a feed screw, having a small backlash and a small clearance in the direction along the axis of the feed screw.

Background

Table mechanisms for precisely moving a workpiece while placing the workpiece thereon are widely used in various industries.

As one of such table mechanisms, for example, a table mechanism disclosed in patent document 1 is known. As shown in fig. 9, the table mechanism is a manual table 200 in which a slide member 204 for mounting a precision device by a fastener and a fixed member 205 connected to a base by a fastener are coupled via a slide mechanism, and the slide member 204 is slid by operating a handle 219, thereby adjusting the position of the mounted precision device.

The fixing member 205 is made of resin. Grooves 232 are formed in the vertical direction in the wall portions on both sides of the fixing member 205 so as to form inverted triangular projections 231.

In the manual table 200, the position of the slide member 204 with respect to the fixed member 205 can be fixed by passing the slide fixing screw 210 through the slide fixing screw hole 216 provided in the wall portion and abutting the projection 231, and pressing the slide member 204 while inclining the projection 231 inward.

Further, the degree of sliding between the fixing member 205 and the slide member 204 can be finely adjusted by inserting a plurality of slide adjusting screws (not shown) through a plurality of slide adjusting screw holes 215 provided in the wall portions on both sides of the fixing member 205, making contact with the protruding portion 231, and pressing the slide member 204 by inclining the protruding portion 231 inward.

As another table mechanism, for example, a table fixing device disclosed in patent document 2 is known.

As shown in fig. 10, the table fixture is a table fixture 300 including a base 301, a fixed table 302, a table 303 for fixing a workpiece, and processing shafts 304 and 306. The table fixing device 300 is capable of fixing the table 303 at a predetermined position by adjusting the position of the table 303 by the processing shafts 304 and 306.

According to this table fixing device 300, it is said that a high-precision table can be fixed with high precision and firmly.

On the other hand, the applicant has proposed, for example, in patent document 3, a table mechanism which has a simple structure with a small size and at low cost, and which has a movable table that slides easily and stably, and which has little backlash when the movable table is fixed and little movement after the movable table is fixed.

As shown in a perspective view of fig. 11 (a) and a cross-sectional view of fig. 11 (b) (a cross-sectional view of fig. 11 (a) taken along line a-a), the table mechanism is a table mechanism 400 including a fixed table 401 and a movable table 403 that slides along a surface of the fixed table 401.

Specifically, as shown in fig. 11 (b), the table mechanism 400 includes a feed screw 405 and a backlash absorbing portion 407 in a fixed table 401, and includes a coupling member 409 for sliding the movable table 403 in synchronization with the feed of the feed screw 405.

In fig. 11, reference numeral 409a denotes a connecting member fixing member, and 405a denotes a feed screw locking member.

Patent document 1: japanese laid-open patent publication No. 2010-223611 (the scope of patent claims)

Patent document 2: japanese patent laid-open No. 2003-48129 (claims, etc.)

Patent document 3: japanese patent No. 4838402 (claims of the patent claims, etc.)

However, the manual table disclosed in patent document 1 has the following problems: the dovetail groove slide guide rail is a leading rail, and a sliding fixing lead screw, a plurality of sliding adjusting lead screws, and the like are required, so that the number of parts is large, the structure is complicated, and a large backlash is generated when the manual workbench is fixed, and the fixation of the manual workbench is insufficient.

Further, the table fixing device disclosed in patent document 2 has a problem that the entire table is large in size because two processing shafts must be provided to protrude to the outside of the table (i.e., from the outer periphery of the table). And a large backlash is generated when the table is fixed, so that there is a problem that the fixability of the table is insufficient.

Further, although the table mechanism disclosed in patent document 3 exhibits extremely good backlash reducing performance, there is a demand for further miniaturization because the coupling portion including the feed screw protrudes from the side of the fixed table. Further, since the feed screw is slightly heavy in operability, improvement thereof is also desired.

Disclosure of Invention

The present invention has been made in view of the above problems, and it is an object of the present invention to provide a new table mechanism which includes a feed screw, has a small backlash, has a small clearance in the direction along the axis of the feed screw, and is easy to miniaturize.

In order to achieve the object, the inventors of the present application have made intensive studies on a structure for attaching a feed screw to a fixed table and a structure in the vicinity of both end portions in the axial direction of the feed screw, while effectively utilizing the function of a backlash absorbing portion created by the inventors.

As a result, it has been found that the above object can be achieved by the following configuration.

Therefore, according to the present invention, there is provided a table mechanism capable of solving the above-described problems, the table mechanism including a feed screw, a fixed table having a space portion in which the feed screw is incorporated, a movable table performing a predetermined operation in accordance with a rotational movement of the feed screw, and a backlash absorbing portion preventing backlash of the feed screw, the table mechanism including: a deviation preventing part which is arranged near the 1 st end part which is one end of the feed screw, contacts with the wall of the space part and prevents the feed screw from deviating towards the 1 st end part; and a pressing force adjusting portion having one end contacting the 2 nd end portion, which is the other end of the feed screw, and the other end fixed to a wall of the space portion, for adjusting a pressing force for pressing the feed screw in a direction from the 2 nd end portion toward the 1 st end portion.

That is, since the backlash absorbing section, the predetermined deviation preventing section for the feed screw, and the pressing force adjusting section for the feed screw are provided, a new table mechanism can be provided which has a small backlash, a small clearance in the direction along the axis of the feed screw, and is easy to be downsized.

In the case of configuring the table mechanism of the present invention, the pressing force adjusting portion preferably includes a structural member in line contact or point contact with respect to the 2 nd end portion of the feed screw.

With this configuration, when the feed screw is rotated, the frictional force generated between the 2 nd end portion and the pressing force adjusting portion can be reduced, and the table can be smoothly moved.

In configuring the table mechanism of the present invention, it is preferable that the pressing force adjusting portion includes a columnar member, and one of a surface of the pressing force adjusting portion facing the 2 nd end portion and a surface of the 2 nd end portion facing the pressing force adjusting portion is formed in a spherical shape, and the other is formed in a concave shape having a surface contacting a surface tangent to the spherical shape.

With this configuration, the gap along the axis of the feed screw can be reduced, and the gap in the direction perpendicular to the axis of the feed screw can also be reduced.

In the table mechanism of the present invention, it is preferable that the pressing force adjusting portion includes a spherical member and a spherical pressing member having a concave portion at a tip thereof, the concave portion having a shape that contacts a surface tangent to the spherical member, the spherical pressing member having a concave portion at a tip thereof, the concave portion having a surface that contacts a surface tangent to the spherical member, the spherical pressing member being sandwiched between the spherical pressing member and the spherical pressing member along the axis of the feed screw.

With this configuration, the gap in the direction perpendicular to the axis of the feed screw can be reduced, and the standard member can be used as the member having the spherical structure, which facilitates mass production.

In the table mechanism of the present invention, the pressing force adjusting portion preferably includes a screw member for pressing the 2 nd end portion of the feed screw.

With this configuration, even when the table is provided, the pressing force to the feed screw can be set, and the position of the table can be adjusted with higher accuracy.

In the table mechanism of the present invention, it is preferable that the pressing force adjusting unit includes a rotary jig connecting unit (in some cases, referred to as a 2 nd rotary jig connecting unit) to which a rotary jig for rotating the screw member is attachable and detachable.

With this configuration, the operability of the position adjustment can be further improved without using a separate special tool.

In the table mechanism of the present invention, it is preferable that the displacement prevention unit includes a protrusion that protrudes in a direction perpendicular to the axis of the screw shaft so that a distance between a surface of the displacement prevention unit on the 1 st end side and an end surface of the 1 st end is equal to or less than T [ mm ] when the thickness of the wall of the space is T [ mm ].

With this configuration, the 1 st end is fitted into the wall of the space, and further downsizing is possible.

In the work table mechanism of the present invention, it is preferable that the 1 st end of the feed screw includes a rotary jig connecting portion (in some cases, the 1 st rotary jig connecting portion is referred to) to which a rotary jig for rotating the feed screw is attachable and detachable.

With this configuration, in the stage of adjusting the position of the table, the position adjustment operation can be easily performed in a state where the rotary jig is attached, and the rotary jig can be used even in a narrower installation space in a state where the rotary jig is detached after the position determination.

In the table mechanism of the present invention, the backlash absorbing portion preferably includes a cylindrical resin member having a through hole for the feed screw.

With this configuration, the gap formed between the feed screw and the backlash absorbing portion can be filled, the backlash can be further reduced, and the accuracy in adjusting the position of the movable table can be further improved.

In the table mechanism of the present invention, the backlash absorbing portion preferably has a metal shield around the backlash absorbing portion.

With this configuration, the entire backlash absorbing portion can be prevented from being deformed, and the accuracy in adjusting the position of the movable table can be further improved.

In the case of constituting the table mechanism of the present invention, the resin member is preferably constituted by at least one of an amide resin, a urethane resin, and a rubber-based resin.

With this configuration, the wear caused by the rotation of the feed screw is reduced, so that the increase of backlash due to repeated use can be more effectively prevented, and the highly accurate position adjustment of the movable table can be realized for a longer period of time.

Drawings

Fig. 1 (a) is a perspective view of the table mechanism 10 of the embodiment, and fig. 1 (b) is a cross-sectional view of the table mechanism 10 obtained when the table mechanism is cut along the line a-a in fig. 1 (a).

Fig. 2 is an exploded perspective view of the table mechanism 10 of the embodiment.

Fig. 3 (a) is a view for explaining an example of mounting the backlash absorbing portion (cylindrical resin member), and fig. 3 (b) is a view for explaining a metal shield at the backlash absorbing portion.

Fig. 4 (a) is a diagram for explaining the operation and effect of the backlash absorbing portion, fig. 4 (b) is a partially enlarged view of the diagram shown in fig. 4 (a), and fig. 4 (c) is a partially enlarged view showing the structure of another backlash absorbing portion.

Fig. 5 (a) is an exploded view of a part of the table mechanism 10 focusing particularly on the deviation preventing portion and the pressing force adjusting portion, and fig. 5 (b) to (c) are partial cross-sectional views obtained when the table mechanism is cut along the line a-a of fig. 5 (a).

Fig. 6 (a) is an exploded view of a part of the table mechanism 10 focusing particularly on the rail structure, and fig. 6 (b) is a cross-sectional view taken along the line a-a of fig. 6 (a).

Fig. 7 (a) to (c) are diagrams illustrating another embodiment of the pressing force adjusting portion.

Fig. 8(a) is a perspective view showing another embodiment of the rail structure, fig. 8 (b) is a cross-sectional view taken along the line a-a in fig. 8(a), and fig. 8 (c) is a cross-sectional view of another example of the rail structure at the same position as fig. 8 (b).

Fig. 9 is a perspective view for explaining a conventional manual table.

Fig. 10 is a perspective view for explaining another conventional table fixing device.

Fig. 11 (a) is a perspective view for explaining still another conventional table fixture, and fig. 11 (b) is a cross-sectional view taken along line a-a of fig. 11 (a).

Detailed Description

Hereinafter, embodiments of the table mechanism according to the present invention will be described with reference to the drawings. The drawings for explanation are only schematically shown to the extent that the present invention can be understood.

In the drawings for explanation, the same components are denoted by the same reference numerals, and explanations thereof may be omitted.

In addition, the shapes, dimensions, materials, and the like described in the following description are merely preferable examples within the scope of the present invention. Therefore, the present invention is not limited to the following embodiments.

[ embodiment 1 ]

As embodiment 1, the main structure is constituted by at least a feed screw, a fixed table, a movable table, a backlash absorbing portion, a deviation preventing portion, a 1 st rotation jig connecting portion, a pressing force adjusting portion, a 2 nd rotation jig connecting portion, and a guide rail, and the movable table is linearly moved by the guide rail moving along two grooves provided in the fixed table.

Fig. 1 (a) is a perspective view showing the entire table mechanism 10 according to embodiment 1, and fig. 1 (b) is a cross-sectional view of the table mechanism 10 taken along line a-a in fig. 1 (a).

Fig. 2 is a perspective view showing a state in which the table mechanism 10 is disassembled.

The table mechanism 10 includes a feed screw 11, a fixed table 13 having a space 13a (see fig. 1 (b) and 2) in which the feed screw 11 is incorporated, a movable table 15, a backlash absorbing portion 17, a deviation preventing portion 19, and a pressing force adjusting portion 21.

Hereinafter, a specific structure and a relationship between these structures will be described as embodiment 1. However, in the drawings, the structures indicated by numerals 31a, 31b, 31c, and 31d are screws or screw holes for fixing the respective members constituting the table mechanism 10, and the structures indicated by numerals 31d and 31e are screws or screw holes for regulating the gap between the guide rail 35 (see fig. 2) and the like.

Further, a structure indicated by numeral 33 is a cylindrical positioning pin for regulating the gap between the movable table 15 and the backlash absorbing portion 17, and a structure indicated by numeral 33a is a screw hole to which a jig for inserting and removing the positioning pin 33 can be attached and detached. The scale indicated by numeral 36 is a movement amount measurement scale for determining the movement amount of the movable table 15, and is a scale having a so-called main scale and a sub scale.

1. Feed screw

The feed screw 11 is a member having a predetermined length and formed with a predetermined pitch of thread teeth. The feed screw 11 can be made of, for example, a metal material subjected to rust-proof treatment.

One end of the feed screw 11 in the axial direction is referred to as a 1 st end portion 11d, and the other end is referred to as a 2 nd end portion 11 e.

2. Fixed working table

(1) Overall size

The fixed table 13 is a base of the table mechanism 10, and is generally rectangular (including square) in planar shape, and is preferably a fixed table having a longitudinal width of 2 to 10cm, a lateral width of 2 to 10cm, and a thickness of 1 to 10mm, for example, as dimensions.

The fixing table 13 includes, for example, an elongated counter bore portion, a wall 13b surrounding the space portion 13a, and holes 13c and 13d provided in portions of the wall 13b facing both end surfaces of the feed screw 11, as the space portion 13a in which the feed screw 11 is incorporated (see fig. 1b and 2).

The reason is that: by having such an overall size, sufficient strength as a table can be maintained, and other structural elements can be easily arranged.

(2) Size of

The fixing table 13 is preferably formed to have a thickness of a wall of the space in the fixing table, for example, T [ mm ] is set to a value in a range of 1 to 10 mm.

The reason is that: the bearing supporting the 1 st end 11d of the feed screw 11 can maintain sufficient strength, and can suppress frictional resistance with the hole 13c opened in the wall of the space portion when the feed screw rotates.

(3) Species of

The material constituting the stationary table 13 is usually aluminum (including anodized aluminum), copper, brass, iron, nickel, magnesium, tungsten, ceramic, a polymer resin material, or the like. In particular, anodized aluminum is preferable as a material constituting the stationary table 13 because it is excellent in light weight, corrosion resistance, durability, workability, thermal conductivity, decorativeness, and economy.

3. Movable working table

The movable table 15 performs a predetermined operation in accordance with the rotational movement of the feed screw 11, and in this case, linearly moves in a direction along the axis of the feed screw 11 within a plane parallel to the surface of the fixed table 13.

Therefore, in this case, the bracket 17a is fixed to the movable table 15. And the backlash absorbing part 17 is fixed in the bracket 17 a. Then, the feed screw 11 is inserted into the backlash absorbing portion 17. As a result, the rotary motion of the feed screw 11 is converted into the linear motion of the movable table 15, and the movable table 15 moves linearly on the fixed table 13.

The cushion resin member 17d is made of resin and functions as a part of the backlash absorbing portion 17 of the feed screw 11 (details will be described later). The movable table 15 may be the same in size and material as the fixed table 13, for example.

4. Backlash absorbing part

(1) Use of

The backlash absorbing portion 17 is a member for ensuring good mobility of the movable table 15, absorbing stress generated in the movable table 15 and the like, suppressing generation of backlash, and stably maintaining a fixed state.

That is, according to the backlash absorbing portion 17, since a predetermined sliding property is exhibited while the movable table 15 slides, it becomes easy to prevent lateral rocking, twisting, and the like without inhibiting the sliding of the movable table 15. Further, when the movable table 15 is fixed, the movable table 15 is appropriately deformed to reduce backlash of the movable table 15, and after the fixing, the movable table is sufficiently cured to similarly absorb stress generated in the movable table 15 and the like, so that it is easy to stably maintain the fixed state.

Therefore, as shown in the sectional view of the backlash absorbing portion shown in fig. 3, the backlash absorbing portion 17 of this embodiment is preferably a cylindrical cushion resin member 17d having a through hole 17c for passing the feed screw 11 therethrough.

That is, by configuring the backlash absorbing portion 17 in this way, the backlash absorbing portion 17 can be easily attached to a predetermined portion of the feed screw 11, the stress absorption by the backlash absorbing portion 17 can be easily performed, and excellent mobility and fixability of the movable table 15 can be easily obtained.

(2) Species of

The material of the cushion resin member 17d in the backlash absorbing section 17 is not particularly limited, but is preferably made of at least one resin material selected from among amide resins (nylon resins), urethane resins, esterified resins, carbonate resins, acrylic resins, olefin resins, rubber-based resins (natural rubbers, styrene rubbers, butadiene rubbers, styrene-butadiene-styrene block copolymers (SBS), styrene-isoprene-styrene block copolymer buffers (SIS), styrene-ethylene-butylene-styrene block copolymer buffers (SEBS), and the like), imine resins, amide-imine resins, phenoxy resins, polyethersulfone resins, polyetheretherketone resins, silicone resins, epoxy resins, cyano resins, guanamine resins, urea resins, and phenol resins.

The reason is that: the backlash absorbing portion 17 made of such a thermoplastic resin material or thermosetting resin material can improve moldability, backlash absorption, and the like of the backlash absorbing portion 17, and can obtain excellent mobility and fixability of the movable table 15.

In particular, at least one of an amide resin (nylon resin), a urethane resin, and a rubber resin is a preferable resin material because the movable table 15 has a better balance between the movability and the fixability and is also excellent in durability and the like.

(3) Glass transition point

In addition, it is preferable to set the glass transition point (in the case of amorphous resin) or the melting point (in the case of crystalline resin) of the constituent material (resin material) of the cushion resin member in the backlash absorbing part 17 to a value generally in the range of 30 to 250 ℃.

The reason is that: if the glass transition point or melting point of the constituent material is less than 30 ℃, heat resistance and mechanical strength are insufficient, and the backlash absorption and the fixing property of the movable table 15 may be reduced.

On the other hand, if the glass transition point or the melting point of the constituent material is a value exceeding 250 ℃, the type of usable resin material may be excessively limited, and the backlash absorption may be significantly reduced.

Therefore, the glass transition point or the melting point of the constituent material of the backlash absorption portion 17 is more preferably set to a value within a range of 50 to 200 ℃, and still more preferably to a value within a range of 80 to 180 ℃.

The glass transition point of the constituent material of the backlash absorption portion 17 can be measured as the change point of the specific heat in the DSC measurement, and in the case of the constituent material having a melting point, it can be measured as the DSC melting heat peak temperature according to jis k 7121.

(4) Metal protective cover

As shown in fig. 1 (b), 2, and 3 (a) to (b), the backlash absorbing portion 17 preferably has a metal shield 17b of a predetermined shape around the backlash absorbing portion.

That is, as shown in fig. 3, it is preferable that the backlash absorbing portion 17 is configured by integrally including a metal protective cover 17b including a cap-shaped housing portion 17e housing the cushion resin member 17d and a screw portion 17f having a screw groove, and inserting the cushion resin member 17d in the arrow direction in fig. 3 (a) to (b).

The reason is that: by providing the metal cover in this manner, the backlash absorbing portion can be easily attached to and fixed to a predetermined portion of the feed screw, and the durability of the backlash absorbing portion is improved, so that excellent mobility and fixation of the movable table can be obtained over a long period of time.

As shown in fig. 4 (a) to (b), it is also preferable that the distal end portion of the cap-shaped housing portion 17e is bent after the metal protection cover 17b is inserted into the cushion resin member 17 d.

The reason is that: by bending in this manner, the cushion resin member can be prevented from falling off, and the backlash absorbing portion can be made more movable with respect to the feed screw and can be made more excellent in stress absorbing performance.

Further, the constituent material of the metal boot is also not particularly limited, but at least one of aluminum, copper, nickel, iron, and the like is preferable because it is lightweight and inexpensive, and predetermined deformability and durability can be obtained.

(5) Effect 1

Here, the effect of the stress absorption by the backlash absorbing portion 17 will be described with reference to (a) to (c) of fig. 4.

That is, fig. 4 (a) is a diagram for explaining the operation and effect of the backlash absorbing portion 17, and shows a state in which the feed screw shaft 11 and two backlash absorbing portions 17 (the cushion resin member 17d having the metal protective cover 17 b) are mounted in the space (the countersink portion) 13a formed in the fixed table 13.

Fig. 4 (b) is a partially enlarged view of the two backlash absorbing portions 17 shown in fig. 4 (a), and shows a state in which the respective metal protecting covers 17b are arranged to face each other and overlap each other.

Fig. 4 (c) shows a state in which two backlash absorbing portions 17 are arranged so that the metal guard 17b faces the feed screw 11 in the same direction (in the right direction in the drawing).

Therefore, even when two backlash absorbing portions 17 are provided as shown in (a) to (c) of fig. 4, as well as when one backlash absorbing portion 17 is provided, the cushion resin member 17d and the like exhibit predetermined slidability during the rotational movement of the feed screw 11 in the predetermined direction, and the movement of the movable table 15 that slides synchronously is not inhibited, and lateral rocking, twisting, and the like can be effectively prevented.

Further, although a heat generation phenomenon may occur along with the rotational movement of the feed screw 11, the two backlash absorbing portions 17 can efficiently absorb heat generated by the heat generation phenomenon.

That is, the backlash absorbing portion 17 may be partially plasticized by the absorbed heat, but a predetermined sliding property and the like can be exhibited as they are.

Further, since the predetermined metal protective cover 17b is provided around the cylindrical cushion resin member 17d constituting the backlash absorbing portion 17, the cushion resin member 17d is not excessively deformed or flows out from a predetermined portion.

(6) Effect 2

On the other hand, as shown in fig. 4 (a) to (c), when two backlash absorbing portions 17 are provided, when the rotational movement of the feed screw 11 is stopped and the synchronized position of the movable table 15 is fixed, the two backlash absorbing portions 17 are appropriately deformed, and the backlash of the movable table 15 can be further reduced.

That is, although the repulsive stress of the return of the movable table 15 is generated as a reaction to the pressing force caused by the rotational movement of the feed screw 11, the backlash absorbing portion 17 is appropriately deformed to efficiently absorb the repulsive stress, and the backlash in the movable table 15 can be further reduced.

After the movable table 15 is fixed at a predetermined position, the cylindrical cushion resin member 17d included in the two backlash absorbing portions 17 is in a sufficiently cured state.

Therefore, in the case of the backlash absorbing portion 17 shown in fig. 4 (a) to (c), the left backlash absorbing portion 17 can efficiently absorb the external stress applied to the feed screw 11 from the left side in the drawing, and the right backlash absorbing portion 17 can efficiently absorb the external stress applied to the feed screw 11 from the right side in the drawing.

Further, even when a stress such as a backlash occurs in one of the two backlash absorbing portions 17, a so-called double nut effect is exhibited.

Therefore, the occurrence of looseness caused by the cushion resin members 17d in the two backlash absorbing portions 17 is effectively prevented, and even if stress for moving the movable table 15 is applied from the outside, the stress can be effectively absorbed, and the fixed state can be more firmly maintained.

5. Deviation prevention part

Next, the deviation preventing unit 19 will be described mainly with reference to fig. 1 (b) and 5 (a). Fig. 5 (a) is a perspective view showing an exploded perspective view of the shift preventing unit 19 and the pressing force adjusting unit 21, as shown in fig. 2.

The deviation preventing portion 19 prevents the feed screw 11 from deviating in the direction toward the 1 st end portion 11 d.

The deviation preventing portion 19 is provided near the 1 st end portion 11d, which is one end of the feed screw 11, and contacts the wall 13b of the space portion 13a of the fixing table 13 in which the feed screw 11 is built.

Specifically, the deviation preventing portion 19 of the present embodiment preferably includes at least a protruding portion 19a, and the protruding portion 19a protrudes from the end surface 11a of the 1 st end portion 11d in a direction perpendicular to the axis of the feed screw at a position having a dimension T [ mm ] or less.

The reason is that: by configuring the projection portion in consideration of the dimension T [ mm ] and the like as described above, the projection portion comes into contact with the wall, so that the displacement of the feed screw in the direction outward from the 1 st end portion side is restricted, and the displacement of the feed screw can be prevented.

And because: since the 1 st end portion is accommodated in the hole of the wall, the member can be prevented from protruding to the outside of the table mechanism, and therefore, the table mechanism can be further miniaturized.

Further, the deviation preventing portion 19 preferably includes a sliding performance improving portion 19b that improves sliding performance between the protruding portion 19a and the wall 13b of the space portion 13 a.

The reason is that: by reducing the radial torque when rotating the feed screw, the operation of position adjustment becomes easier.

Here, the projection 19a is a disk-shaped member that is larger than the diameter of the feed screw 11 and is concentric with the feed screw 11. In addition, the hole 13c is a hole into which the 1 st end 11d of the feed screw 11 is inserted and has a bore with an appropriate tolerance.

In order to further reduce the radial torque of the feed screw, it is preferable to adopt a structure in which a treatment with good slidability is performed on the inner surface of the hole, or a ring with good slidability is provided.

6. 1 st rotating jig connecting part

Further, it is preferable that the 1 st rotating jig connecting portion 11c is provided on the 1 st end portion 11d side end surface 11a of the feed screw 11.

Specifically, the 1 st rotary jig connecting portion 11c is a structural portion that is detachably connected to the 1 st end portion 11d of the feed screw from the outside of the table mechanism 10, for example, by using a rotary jig such as a hexagon wrench (not particularly shown), a screwdriver (not particularly shown), or a dedicated knob 25 for rotating the feed screw 11. More specifically, the 1 st rotating jig connecting portion 11c is preferably a hexagonal inner hole or the like, for example.

The reason is that: by providing the 1 st rotary jig connecting portion, the rotary jig can be removed at a time other than the time of adjustment of the table mechanism, and therefore, the member does not protrude outward from the 1 st end portion side of the table mechanism, and the table mechanism can be further miniaturized.

7. Pressing force adjusting part

Next, the pressing force adjusting portion 21 will be described mainly with reference to fig. 1 (b) and 5 (a). Fig. 5 (a) is a perspective view showing an exploded perspective view of the shift preventing unit 19 and the pressing force adjusting unit 21 in fig. 2.

Fig. 5 (b) is a cross-sectional view of the 2 nd end portion 11e of the feed screw 11 and the pressing force adjusting portion 21 obtained when the feed screw is cut along the line a-a in fig. 5 (a). Fig. 5 (c) is a cross-sectional view showing the same position as fig. 5 (b) in order to explain a modification of the pressing force adjusting portion 21.

The pressing force adjusting unit 21 is a member that adjusts the pressing force for pressing the feed screw 11 from the 2 nd end portion 11e to the 1 st end portion 11 d. The pressing force adjusting portion 21 is a member having one end in contact with the 2 nd end portion 11e of the feed screw 11 and the other end fixed to the wall 13b of the space portion 13a of the fixed table 13.

The pressing force adjusting portion 21 is preferably a structural member that makes line contact or point contact with the 2 nd end portion 11e of the feed screw 11.

The reason is that: since the contact area between the pressing force adjusting portion and the 2 nd end portion of the feed screw is smaller than that in the case where both are in surface contact, the radial torque, which is the force for rotating the feed screw, can be reduced, and the operability of the feed screw can be further improved.

In consideration of stability of the pressing force applied to the feed screw, the pressing force adjusting portion 21 is preferably in a line contact structure as compared with a point contact structure with respect to the feed screw 11.

The reason is that: in the case of the line contact, even when a force is applied in a direction perpendicular to the axis of the feed screw in accordance with the movement of the carriage, the axis deviation can be further prevented.

For example, as shown in fig. 1 (b) and 5, the pressing force adjusting portion 21 having such a line contact structure includes a spherical surface (a spherical member 21a in the example of the drawing) and a spherical surface pressing member 21b having a surface that contacts a surface tangent to the spherical surface.

As a more specific example, as shown in fig. 5 (b), there can be mentioned a spherical pressing member 21b having a mortar-like recess structure 21e at the end.

The spherical surface pressing member 21b is configured to be rotatable to the left and right about an axis along the axis of the feed screw 11 as a rotation axis and to be movable to the front and rear along the axial direction of the feed screw 11 in accordance with the rotation.

Further, the pressing force for pressing the feed screw 11 from the 2 nd end portion 11e side toward the 1 st end portion 11d can be adjusted by the rotational operation and the linear movement operation associated with the rotational operation.

The deviation preventing portion 19 and the pressing force adjusting portion 21 are coupled to each other, so that a gap along the axial direction of the feed screw 11 can be further prevented.

The spherical surface pressing member 21b is not limited to this, and may be formed of, for example, a hexagon socket set screw having a mortar-like structure as described above at the tip thereof so as to have a V-shape when a cross section including the shaft of the feed screw is viewed.

Modification example 1

As another example of the pressing force adjusting portion 21 having a structure in line contact with the spherical surface, it is preferable to use a columnar member 21d having a terminal processed into a spherical shape, as shown in fig. 5 (c) by the same cross section as fig. 5 (b).

The reason is that: the spherical portion may not be used, and accordingly, the structure of the pressing force adjusting portion can be simplified.

In the example of fig. 5 (c), the spherical surface pressure receiving portion 11b having a mortar-shaped concave structure is provided at the tip of the 2 nd end portion 11e of the feed screw 11, and the tip of the pressing adjustment portion is machined to be spherical.

That is, the following configuration may be adopted: the tip of the 2 nd end portion 11e of the feed screw 11 is machined into a spherical surface, and the tip of the press adjustment portion on the 2 nd end portion 11e side is configured to be a mortar-shaped concave portion.

In the above, an example of a structure in which the pressing force adjusting portion 21 presses the 2 nd end portion 11e of the feed screw 11 in a line contact manner has been described, but the structure of the pressing force adjusting portion is not limited to this.

A modification of the pressing force adjusting portion will be described below with reference to fig. 7. Each of fig. 7 is a sectional view similar to fig. 1 (b), and particularly, a sectional view focusing on the pressing force adjusting portion.

(2) Modification 2

The pressing force adjusting portions 21 in fig. 7 (a) to (b) are all examples using a pivot structure. In particular, the pressing force adjusting portion 21 shown in fig. 7 (a) is an example in which the pressing force adjusting portion 21 is constituted by a columnar member 21m having a structure in which a tip is processed into a triangular cone shape so as to correspond to the concave portion, with respect to the 2 nd end portion 11e having the concave portion capable of receiving the triangular cone. With such a configuration, the end can be easily processed as compared with the case where the end is formed into a spherical shape, so that mass production is easy, and the structure of the pressing force adjusting portion can be further simplified by eliminating the use of the spherical member.

(3) Modification 3

The pressing force adjusting portion 21 shown in fig. 7 (b) is an example in which the pressing force adjusting portion 21 is constituted by a columnar member 21n having a structure in which a tip is processed into a spherical shape so as to correspond to the concave portion, with respect to the 2 nd end portion 11g having the spherical concave portion. With such a configuration, the contact area between the 2 nd end portion and the columnar member is increased, and therefore, even when the pressing force of the pressing adjustment portion is increased, the wear associated with the rotation of the feed screw can be further reduced.

(4) Modification example 4

The pressing force adjusting portion 21 shown in fig. 7 (c) is an example in which the pressing force adjusting portion 21 is formed by a columnar member 21p having a concave portion at the end thereof corresponding to a convex shape of the 2 nd end portion 11h having the end processed into the predetermined shape. With this configuration, even when a force is applied in a direction perpendicular to the axis of the feed screw, the axis can be further prevented from being deviated.

8. No. 2 rotating jig connecting part

In addition, in the present invention, it is preferable that a 2 nd rotating jig connecting part 21c (see (b) of fig. 1) is provided on an outer end surface of the pressing force adjusting part 21.

The 2 nd rotary jig connecting portion 21c is a structural portion for detachably connecting a rotary jig for rotating a pressing force adjusting portion, such as a hexagonal wrench (not particularly shown), a screwdriver (not particularly shown), or a dedicated knob 25, to the pressing force adjusting portion from the outside of the table mechanism 10. Specifically, for example, a hexagonal inner hole is preferable.

The reason is that: by adopting the structure of providing the 2 nd rotary jig connecting portion, the rotary jig can be removed at a time other than the time of adjustment of the table mechanism, and therefore, the member does not protrude to the outside of the 2 nd end portion side of the table mechanism, and the table mechanism can be further miniaturized.

9. Guide rail

In the table mechanism 10, a guide rail is provided on the fixed table 13 in order to regulate the sliding direction of the movable table 15. The structure of the guide rail will be described below.

Fig. 6 is an explanatory view thereof, and particularly fig. 6 (a) is a main part perspective view showing an exploded perspective view shown in fig. 2 with attention paid to the guide rail 35, and fig. 6 (b) is a sectional view taken along a-a in fig. 6 (a). In two regions of the fixed table 13 which are separated from each other and which are parallel to the feed screw, long grooves 35a for accommodating the guide rails 35 are provided.

On the other hand, in two regions of the movable table 15 separated from each other, and in two regions corresponding to the grooves 35a provided in the fixed table 13, long grooves 35b for accommodating the guide rails 35 are provided. The guide rails 35 are provided in the grooves 35b on the movable table 15 side, and one of the side surfaces of the guide rails 35 is pressed by the fixing screws 41.

The fixing screw 41 is screwed into a screw hole for the fixing screw 41 provided on the side surface of the movable table 15, and reaches the side surface of the guide rail 35, thereby pressing the guide rail 35. When the movable table 15 moves, the movement direction of the movable table 15 can be further restricted by the guide rail 35 and the groove 35a on the fixed table 13 side.

In the above, an example in which two guide rails and a groove for restricting the movement of the guide rails are used has been described as the guide structure, but the guide structure is not limited to this example.

[ 2 nd embodiment ]

As embodiment 2, the main structure is constituted by at least a feed screw, a fixed table, a movable table, a backlash absorbing portion, a deviation preventing portion, a 1 st rotary jig connecting portion, a pressing force adjusting portion, and a 2 nd rotary jig connecting portion, and the movable table is configured to move linearly by a movable table gate-type straddle portion straddling over a convex portion of the fixed table corresponding to the gate-type straddle portion.

Hereinafter, another example of the guide structure will be described as embodiment 2 with reference to fig. 8. Each of fig. 8 is a perspective view and a cross-sectional view shown in the same manner as fig. 6.

The guide structure shown in fig. 8(a) to (b) is configured such that the convex guide 35c is provided in a predetermined region of the fixed table 13, the guide rail is provided so as to sandwich the convex guide 35c, and the gate-type straddle seat 35d is provided in a region of the movable table 15 corresponding to the convex guide 35 c.

1. Feed screw

Although not shown in fig. 8, the feed screw is a member having a predetermined length with a predetermined pitch of thread ridges, as in embodiment 1. The feed screw may be made of, for example, a metal material subjected to rust-proof treatment.

2. Fixed working table

The fixed table 13 is configured by removing the groove for the rail of the fixed table of embodiment 1 and providing the convex guide 35 c. The fixed table 13 is a base of the table mechanism 10, and is generally rectangular (including a square) in plan view, and the fixed table 13 has a vertical width of, for example, 2 to 10cm, a horizontal width of 2 to 10cm, and a thickness of 1 to 10mm, as dimensions thereof.

After the movable table 15 and the guide rail 35 are mounted on the fixed table 13, the side surface of the convex guide 35c is appropriately pressed by the guide rail while being sandwiched by the guide rail by pressing the guide rail 35 with the fixing screw 41 screwed from the side surface of the movable table 15 into the hole for the fixing screw provided in the movable table 15. Therefore, the movable table 15 is restricted by the convex guides 35c to move. With this configuration, groove processing that causes the occurrence of a gap in embodiment 1 is not necessary, and therefore the position of the table can be adjusted with higher accuracy.

Fig. 8 (c) shows an example in which a guide structure is constituted by a dovetail groove 35e and a guide 35f having a reverse-tapered convex structure corresponding to the dovetail groove 35e, instead of the guide rail shown in fig. 8(a) to (b). With this configuration, even when a force acts in the direction in which the fixed table and the movable table are separated from each other, the inverted-cone-shaped convex portion can suppress the displacement, and the position of the table can be adjusted with higher accuracy.

3. Movable working table

The movable table 15 is configured by removing a groove for a guide rail of the movable table of embodiment 1 and providing a portal straddle seat portion 35 d. The movable table 15 performs a predetermined operation in accordance with the rotational movement of the feed screw (not particularly shown), and in this case, linearly moves in a direction along the axis of the feed screw (not particularly shown) within a plane parallel to the surface of the fixed table 13. With this configuration, groove processing that causes the formation of the gap in embodiment 1 is not necessary, and therefore the position of the table can be adjusted with higher accuracy.

Further, by providing the guide structure with a dovetail groove structure, the guide rail is not required, the number of components can be reduced as compared with embodiment 1, and the position of the table can be adjusted with higher accuracy.

4. Backlash absorbing part

The backlash absorbing portion is not shown in fig. 8, but is a member for ensuring good mobility of the movable table 15, absorbing stress generated in the movable table 15 and the like, suppressing generation of backlash, and firmly maintaining a fixed state, as in embodiment 1. With this configuration, the movable table can exhibit a predetermined sliding property during sliding, and lateral rocking, twisting, and the like can be further prevented without hindering the sliding of the movable table.

Further, when the movable table is fixed, the movable table is appropriately deformed to reduce backlash of the movable table, and after the fixing, the movable table is sufficiently cured to similarly absorb stress generated in the movable table or the like, so that the fixed state can be more firmly maintained.

5. Deviation prevention part

The deviation preventing portion is not shown in fig. 8, but is a member for preventing the feed screw from deviating in the direction of the 1 st end portion side, as in embodiment 1. With this configuration, the 1 st end portion is accommodated in the hole of the wall, and therefore, the member can be prevented from protruding to the outside of the table mechanism, and therefore, the table mechanism can be further downsized.

6. 1 st rotating jig connecting part

Although not shown in fig. 8, the 1 st rotary jig connecting portion is a structural portion that is detachably connected to the 1 st end portion of the feed screw from the outside of the table mechanism, in the same manner as in embodiment 1, for example, by using a rotary jig such as a hexagonal wrench, a screwdriver, or a special knob for rotating the feed screw.

Since the rotating jig can be removed at a time other than the time of adjustment of the table mechanism, the member does not protrude outward from the 1 st end portion side of the table mechanism, and therefore the table mechanism can be further miniaturized.

7. Pressing force adjusting part

The pressing force adjusting portion is not shown in fig. 8, but is a member for adjusting the pressing force for pressing the feed screw in the direction from the 2 nd end portion to the 1 st end portion, as in embodiment 1. With this configuration, the deviation preventing portion and the pressing force adjusting portion are coupled to each other, and a gap along the axial direction of the feed screw can be further prevented.

8. No. 2 rotating jig connecting part

The 2 nd rotary jig connecting portion is a structural portion which is not shown in fig. 8, but is detachably connected to the pressing force adjusting portion from the outside of the table mechanism, similarly to the 1 st embodiment, for connecting a rotary jig for rotating the pressing force adjusting portion, such as a hexagonal wrench, a screwdriver, or a dedicated knob, to the pressing force adjusting portion. With this configuration, since the rotating jig can be removed at a time other than when the table mechanism is adjusted, the member does not protrude outward on the 2 nd end portion side of the table mechanism, and therefore, the table mechanism can be further miniaturized.