KR200491767Y1 - One way rotation unit applied to industrial rack system - Google Patents

Abstract

Disclosed is a one-way rotating unit applied to an industrial rack system. According to the disclosed one-way rotation unit applied to the industrial rack system, it is applied to the industrial rack system and includes a body member, an external force supply member, an external force transmission member, an engagement member, and a rotation member, and supplies the external force The member, the external force transmitting member, the engaging member, and the rotating member are disposed inside the body member, and when the external force supply member is rotated at a predetermined angle by an external force applied to the external force supply member, the The external force transmission member is moved to be relatively close to the external force supply member so that the external force transmission member and the engagement member are spaced apart, and the external force transmission member and the engagement member are engaged by the separation of the external force transmission member and the engagement member. When the engagement force and the rotating member can be freely rotated in both directions, and the external force transmitting member is rotated at an angle in the other direction by an external force applied to the external force supply member, the external force transmitting member is released. The external force transmission member and the engagement member are engaged by being moved relatively far from the external force supply member, and the rotational direction of the engagement member is limited by the engagement of the external force transmission member and the engagement member, and accordingly, the engagement Since the member and the rotating member are rotated in a predetermined direction, the object to be moved can be moved after being rotated in a predetermined direction in a predetermined time in a state applied to the industrial rack system, but it has an advantage that a simple structure can be achieved.

Description

One way rotation unit applied to industrial rack system

The present invention relates to a one-way rotating unit applied to an industrial rack system.

The industrial rack system is to form an industrial structure using a plurality of pipes and a metal joint that can connect the plurality of pipes.

Examples of the industrial structure include an industrial shelf manufactured to suit the situation of the industrial site to which it is applied, a frame for a roller unit applied to a roller unit that moves a moving object along the roller in a state where a plurality of rollers are fastened.

What can be presented as an example of such an industrial structure such as a frame for an industrial shelf and a roller unit is that of the patent documents presented below.

However, according to a conventional industrial rack system, when the object to be moved is rotated by a certain angle, a separate rotating device for moving the object to be moved after rotation is required, and the industrial rack is used to rotate the object. It took a lot of time to attach and detach the system.

In addition, due to the rotation of the rotating device in both directions, there is a problem in that the rotating object and the waiting to be rotated collide with each other and are damaged or a personal accident occurs while colliding with an operator.

Registered Patent No. 10-0912569, Date of registration: 2009.08.10., Name of invention: Goods holder Registered Patent No. 10-0879070, Registration date: 2018.01.09., Name of invention: Bogie transport device

The present invention is applied to the industrial rack system to provide a one-way rotation unit applied to an industrial rack system having a simple structure while being able to rotate and move a moving object in a predetermined time in a predetermined direction by an external force supplied from the outside. It aims at work.

The one-way rotating unit applied to the industrial rack system according to one aspect of the present invention is applied to an industrial rack system in which a plurality of pipes are connected to each other by metal joints to construct an industrial structure, and among the plurality of pipes A body member that can rotate at least one of the pipes inserted therein and constitutes an outer frame; An external force supply member connected to the body member and supplied with an external force; It is connected to the external force supply member to transmit the external force supplied by the external force supply member, and when the external force supply member is rotated at a certain angle in one direction by the external force, it moves to be relatively close to the external force supply member, and supplies the external force An external force transmission member moved when the member is rotated at a predetermined angle in the other direction by the external force to move relatively away from the external force supply member; An engagement member formed in a form of engaging with the external force transmission member to receive the external force transmitted from the external force transmission member; And a rotating member connected to the engaging member and rotated together with the engaging member, the rotating member capable of changing a rotation direction by an external force supplied from the external force supply member. The member, the external force transmitting member, the engaging member, and the rotating member are disposed inside the body member, and when the external force supply member is rotated at a predetermined angle by an external force applied to the external force supply member, the The external force transmission member is moved to be relatively close to the external force supply member so that the external force transmission member and the engagement member are spaced apart, and the external force transmission member and the engagement member are separated from each other by the separation between the external force transmission member and the engagement member. When the engagement force and the rotating member can be freely rotated in both directions, and the external force transmitting member is rotated at an angle in the other direction by an external force applied to the external force supply member, the external force transmitting member is released. The external force transmission member and the engagement member are engaged by being moved relatively far from the external force supply member, and the rotational direction of the engagement member is limited by the engagement of the external force transmission member and the engagement member, and accordingly, the engagement It is characterized in that the member and the rotating member can be rotated in a predetermined direction.

According to the one-way rotation unit applied to the industrial rack system according to an aspect of the present invention, the one-way rotation unit applied to the industrial rack system is applied to the industrial rack system and a body member, an external force supply member, and external force transmission A member, an engaging member, and a rotating member, the external force supply member, the external force transmission member, the engagement member, and the rotating member are disposed inside the body member, and an external force applied to the external force supply member When the external force supply member is rotated by a certain angle in one direction, the external force transmission member is moved to be relatively close to the external force supply member to separate the external force transmission member and the engagement member, and the external force transmission member and the engagement The external force transmission member and the engagement member are disengaged by the separation of the member, so that the engagement member and the rotation member can be freely rotated in both directions, and the external force is applied by an external force applied to the external force supply member. When the transmission member is rotated at a certain angle in the other direction, the external force transmission member is moved to be relatively far from the external force supply member so that the external force transmission member and the engagement member are engaged, and the external force transmission member and the engagement member are engaged. By the rotational direction of the engaging member is limited, and accordingly, the engaging member and the rotating member are rotated in a predetermined direction, so that they are applied to the industrial rack system and are applied to the industrial rack system in a predetermined direction by an external force supplied in a short time. There is an effect that can be made of a simple structure while being able to move the moving object after rotation.

1 is a perspective view of a one-way rotating unit applied to an industrial rack system according to a first embodiment of the present invention, viewed from above.
Figure 2 is an exploded view looking at the exploded view of the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention.
Figure 3 is a front view of a part of the components of the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention as viewed from the front.
4 is a perspective view of a rotating member constituting a one-way rotating unit applied to an industrial rack system according to a first embodiment of the present invention, viewed from above.
5 is an enlarged view of part A of FIG. 2.
Figure 6 is an enlarged view of the external force transmitting member constituting the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention rotated in one direction.
7 is an enlarged view of a state in which the external force transmitting member constituting the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention is rotated in the other direction.
8 is a front view of the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention as viewed from the front.
9 is a cross-sectional view taken along the direction of the arrow BB' in FIG. 8;
10 is a cross-sectional view of CC 8 of FIG. 8 viewed in the direction of an arrow.
11 is a cross-sectional view of DD' of FIG. 8 as viewed in the direction of the arrow.
12 is a cross-sectional view of EE' in FIG. 8 as viewed in the direction of the arrow.
13 is a perspective view of a one-way rotating unit applied to an industrial rack system according to a second embodiment of the present invention, viewed from above.
14 is a front view of the one-way rotating unit applied to the industrial rack system according to the second embodiment of the present invention as viewed from the front.
15 is a view showing a state in which a one-way rotating unit applied to an industrial rack system according to a second embodiment of the present invention is used in an industrial rack system.

Hereinafter, a one-way rotating unit applied to an industrial rack system according to an embodiment of the present invention will be described with reference to the drawings.

1 is a perspective view of a one-way rotation unit applied to an industrial rack system according to a first embodiment of the present invention, viewed from above, and FIG. 2 is a one-way rotation applied to an industrial rack system according to a first embodiment of the present invention 3 is an exploded view looking at the exploded view of the unit from above, FIG. 3 is a front view of a part of the components of the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention, and FIG. The perspective view of the rotating member constituting the one-way rotating unit applied to the industrial rack system according to the first embodiment of the invention is viewed from above, FIG. 5 is an enlarged view of part A of FIG. 2, and FIG. 6 is the It is an enlarged view of the external force transmission member constituting the one-way rotating unit applied to the industrial rack system according to the first embodiment rotated in one direction, Figure 7 is an industrial rack system according to the first embodiment of the present invention 8 is an enlarged view of the external force transmission member constituting the one-way rotating unit applied to the other direction, and FIG. 8 is a front view of the one-way rotating unit applied to the industrial rack system according to the first embodiment of the present invention It is a front view, FIG. 9 is a sectional view seen from BB' in FIG. 8 in the direction of the arrow, FIG. 10 is a sectional view seen from CC' in FIG. 8 in the direction of the arrow, and FIG. 11 is a sectional view taken from DD' in FIG. 8 in the direction of the arrow , FIG. 12 is a cross-sectional view of EE' of FIG. 8 viewed in the direction of the arrow.

Referring to FIGS. 1 to 12 together, the one-way rotating unit 100 applied to the industrial rack system according to the present embodiment is an industrial rack capable of constructing an industrial structure in which a plurality of pipes are connected to each other by metal joints. Applied to the system, as being capable of rotating at least one of the plurality of pipes inserted therein, the body member 110, the external force supply member 120, the external force transmission member 130, It includes an engaging member 140 and a rotating member 150.

When the one-way rotation unit 100 applied to the industrial rack system is configured as described above and the external force supply member 120 is rotated at a certain angle in one direction by an external force applied to the external force supply member 120, The external force transmission member 130 is moved to be relatively close to the external force supply member 120 so that the external force transmission member 130 and the engagement member 140 are spaced apart, and the external force transmission member 130 and the engagement Due to the separation of the member 140, the engagement between the external force transmitting member 130 and the engaging member 140 is released, and accordingly, the engaging member 140 and the rotating member 150 are freely rotated in both directions. Can be.

In addition, the external force transmission member 130 is rotated at a certain angle in the other direction by an external force applied to the external force supply member 120 in a state in which the one-way rotation unit 100 applied to the industrial rack system is configured as described above. When the external force transmission member 130 is moved to be relatively far from the external force supply member 120, the external force transmission member 130 and the engagement member 140 are engaged, and the external force transmission member 130 The rotational direction of the engagement member 140 is limited by the engagement of the engagement member 140, and accordingly, the engagement member 140 and the rotation member 150 can be rotated in a predetermined direction.

The one-way rotating unit 100 applied to the industrial rack system may be made of at least one of a metal material such as aluminum or stainless steel and a synthetic resin such as plastic.

In this embodiment, the one-way rotating unit 100 applied to the industrial rack system further includes an elastic member 160.

The body member 110 constitutes the outer frame of the one-way rotating unit 100 applied to the industrial rack system, the external force supply member 120, the external force transmission member 130, and the engaging member 140 and the rotating member 150 are disposed inside the body member 110.

In detail, the body member 110 includes a body-side body 111, a body-side upper cover 113, a body-side upper fixing means 114, a body-side lower cover 115, and a body-side lower fixing means. (116).

In this embodiment, the body member 110 further includes a body-side lateral groove 112 and a body-side vertical groove 117 formed on an inner surface of the body-side body 111.

The body-side body 111 is formed in a cylindrical shape with an open top and a bottom and an inside, the external force supply member 120, the external force transmission member 130, and the engaging member 140 therein Wow, the rotating member 150 is inserted.

The body-side lateral groove 112 is formed to be recessed at a predetermined depth in a horizontal direction perpendicular to the longitudinal direction of the body-side body 111 from the inner surface of the body-side body 111, the first clamp outside to be described later The protrusion 148 is inserted to fix the first clamp 147 on which the first clamp outer protrusion 148 is formed.

The body-side upper cover 113 covers the upper portion of the body-side body 111, and a through hole through which the rotating member 150 can be inserted is formed in the center thereof.

The body-side upper fixing means 114 is such that the body-side upper cover 113 is fastened to the body-side body 111, and a bolt or the like can be presented as an example.

The body-side lower cover 115 covers the lower portion of the body-side body 111, and a through hole through which the rotating member 150 can be inserted is formed in the center thereof.

The body-side lower fixing means 116 is such that the body-side lower cover 115 is fastened to the body-side body 111, and a bolt or the like can be presented as an example.

A certain space may be formed in the body-side body 111 by combining the body-side upper cover 113 and the body-side lower cover 115.

The external force supply member 120 is inserted and connected to the body member 110, and external force is supplied from the outside by an operator or a tool, and includes an external force supply side body 121 and a side through hole 119.

The external force supplied from the outside is a rotational force for rotating the external force supply member 120.

The external force supply-side body 121 is connected to the body member 110 in a form in which a part thereof is inserted inside the upper side of the body-side body 111, and is included in the rotation member 150 and rotated later as described later The body 151 is formed in a donut shape through which the central portion is inserted so as to be inserted.

The external force supply-side body 121 is formed with an external force supply-side expansion body 122 and an external force applying body 129.

The external force supply-side expansion body 122 is located on the upper surface of the external force supply-side body 121 and is formed in a donut shape through which a central portion is penetrated so that the rotation-side body 151 included in the rotation member 150 is inserted, The outer diameter is formed to be a relatively larger outer diameter than the outer diameter of the external force supply-side body 121 to be placed on the upper surface of the body-side body 111, more precisely the body-side upper cover 113, and the body-side upper portion. It protrudes a certain height over the upper surface of the cover 113.

The external force applying body 129 is formed to extend a predetermined length outward from the external force supply-side expansion body 122, and by transmitting the external force to the external force applying body 129 using the hand or tool of the operator, the external force The supply member 120 may be rotated at an angle.

The external force applying body 129 may be formed in one or more, but in this embodiment, it is easy for the operator to hold the hand or the like, and two are arranged at equal intervals so that a uniform external force is applied from both sides.

Here, the external force transmitted to the external force applying body 129 becomes a rotational force capable of rotating the external force supply member 120 at an angle.

The side through hole 119 is formed through the side of the external force supply side body 121.

In detail, the side through hole 119 includes a plane 123, a first side 124, a second side 125, a first seating surface 126, a second seating surface 128, It includes an inclined surface 127, the plane 123, the first side 124, the second side 125, the first seating surface 126, and the second seating surface 128 ), and a through-sized space of a certain size is formed by the inclined surface 127.

The flat surface 123 is positioned at the same height as the bottom surface of the external force supply side expansion body 122 and is formed in a flat shape in the external force supply side body 121 so as to be parallel to the external force supply side expansion body 122.

The first side surface 124 is formed by bending in a direction perpendicular to the plane 123 downward from the side where the external force transmission member 130 is disposed at one end of the plane 123.

The second side 125 is a side on which the external force transmitting member 130 is disposed at one end of the plane 123 so as to face the first side 124 at the other end of the plane 123. It is formed by bending in the vertical direction with the plane 123, but is formed relatively longer than the first side 124.

The first seating surface 126 extends parallel to the plane 123 at the end of the first side 124.

The second seating surface 128 extends parallel to the plane 123 at an end of the second side surface 125 and is positioned at a different height from the first seating surface 126.

The inclined surface 127 connects the first seating surface 126 and the second seating surface 128, and the lengths of the first side 124 and the second side 125 are different from each other. , The height of the first seating surface 126 and the second seating surface 128 connected to the first side 124 and the second side 125 respectively is changed, and accordingly the inclined surface 127 Degree is also made in the form of a slope with a certain slope.

The external force transmission side lateral protrusions 132 constituting the external force transmission member 130 to be described later are inserted into the side through hole 119, so that the external force supply member 120 and the external force transmission member 130 are connected. .

The side through-hole 119 and the side projection 132 of the external force transmission side may be formed at least one, but in this embodiment, the external force supply member 120 may be rotated in a balanced manner when external force is applied. Two of the external force transmitting side lateral protrusions 132 that are disposed at intervals and inserted into the side through hole 119 are also disposed at equal intervals on both sides.

The external force transmission member 130 is connected to the external force supply member 120 to transmit external force supplied by the external force supply member 120, and the external force supply member 120 is angled in one direction by external force When rotated, it is moved to be relatively close to the external force supply member 120, and when the external force supply member 120 is rotated at an angle in another direction by an external force, it is moved to be relatively far from the external force supply member 120. .

In detail, the external force transmission member 130 includes an external force transmission side body 131, the external force transmission side side protrusion 132, and an external force transmission side contact portion 133.

The external force transmitting side body 131 is formed in a donut shape through which a central portion is penetrated so that the rotating side body 151 included in the rotating member 150 is inserted, and a part of the external force transmitting side body 131 is the external force. It is inserted into the supply member 120.

In detail, a portion of the external force transmitting side body 131 that is relatively close to the external force supply member 120 corresponds to an inner diameter of the external force supply side body 121 so that an external diameter is inserted into the external force supply side body 121. It is formed in a form, the outer force transmission side body 131 of the external force supply member 120, a relatively distant portion of the external force supply side body 121 so that the external force supply side body 121 can be seated It is formed relatively large compared to the inner diameter.

Then, when the external force supply member 120 and the external force transmission member 130 are connected, a portion of the external force transmission member 130 is inserted into the inner hole of the external force supply member 120 while the external force supply member 120 ) Can be seated on the external force transmission member 130.

The external force transmission side side protrusion 132 protrudes a certain length in a circular shape from the side of the external force transmission side body 131, is inserted into the side through hole 119 and moved within the side through hole 119 will be.

Reference numeral 135 is an external force transmission side recessed groove recessed at a predetermined depth in the longitudinal direction of the external force transmission side body 131 on both sides of the external force transmission side side protrusion 132 among the external force transmission side body 131.

The pair of the external force transmitting side recessed grooves 135 is formed to a certain depth, so that the external force transmitting side body 131 on which the external force transmitting side lateral protrusions 132 are formed has a lower portion fixed thereto, and an upper portion thereof is the It is possible to bend a certain angle in the center direction of the body 131 of the external force transmission side.

Then, when the external force transmission side side protrusion 132 is inserted into the side through hole 119, the external force transmission side side protrusion 132 is bent at a certain angle in the center direction of the external force transmission side body 131, After the external force transmission side side protrusion 132 is easily inserted into the side through hole 119, and after the external force transmission side side protrusion 132 is inserted into the side through hole 119, the external force transmission side side The curvature of the projection 132 is restored so that the insertion of the external force transmission side side projection 132 into the side through hole 119 can be maintained satisfactorily.

The external force transmission side contact portion 133 is formed in a sawtooth shape on the bottom surface of the external force transmission side body 131 to be in close contact with the engagement member 140.

In detail, the external force transmission side contact portion 133 protrudes obliquely from the external force transmission side vertical surface 136 protruding in the vertical direction from the bottom surface of the external force transmission side body 131, and the lower surface of the external force transmission side body 131. As it includes the external force transmission side inclined surface 137 which is connected to the end of the external force transmission side vertical surface 136, as shown in Figure 5, the external force transmission side contact portion 133 and the external force transmission side inclined surface ( 137) a plurality of teeth are sequentially connected to each other, thereby forming a sawtooth shape.

The external force transmission member 130 protrudes a predetermined length from the outer surface of the external force transmission side body 131 constituting the external force transmission member 130, is spaced apart from the external force transmission side side protrusion 132 and transmits the external force It further includes an external force transmission side fixing protrusion 134 disposed to be relatively close to the external force transmission side contact portion 133 as compared to the side side protrusion 132.

In addition, the body member 110 further includes the body-side vertical groove 117 formed long in the longitudinal direction of the body member 110 while being inserted at a certain depth from the inner surface of the body member 110.

Then, as illustrated in FIG. 9, the external force transmission side fixing protrusion 134 is inserted into the body side vertical groove 117 so that the external force transmission side fixing protrusion 134 and the body side vertical groove 117 are formed. As it is connected, rotation of the external force transmission member 130 with respect to the body member 110 is prevented.

The external force transmission side fixing protrusion 134 and the body side vertical groove 117 may be formed in one or more, but in this embodiment, the rotation of the external force transmission member 130 with respect to the body member 110 is performed in multiple directions. Four external force transmission-side fixing protrusions 134 are formed at equal intervals to be prevented, and four body-side vertical grooves 117 are also formed at equal intervals to correspond to the external force transmission-side fixing protrusions 134. .

More precisely, the movement of the external force transmission member 130 with respect to the longitudinal direction of the body member 110 is possible, but the external force transmission member with respect to the circular arc direction that becomes the outer diameter of the body member 110 ( 130) rotation is prevented.

The engaging member 140 is located under the external force transmitting member 130 and is formed in a form of engaging with the external force transmitting member 130 to receive the external force transmitted from the external force transmitting member 130 will be.

In detail, the engaging member 140 includes an engaging side body 141, an engaging side contact portion 143, and an engaging side protrusion 142.

The engagement-side body 141 is formed in a donut shape through which a central portion is penetrated so that the rotation-side body 151 included in the rotation member 150 is inserted.

The engagement-side contact portion 143 is formed in a tooth shape corresponding to the external force transmission-side contact portion 133 on the upper surface of the engagement-side body 141 to be engaged with the external force transfer-side contact portion 133. As it is, the engagement member 140 is rotated according to the rotation of the external force transmission member 130 as the engagement side contact portion 143 is in close contact with the external force transmission side contact portion 133.

In detail, the engaging side contact portion 143 is the engaging side vertical surface 146 protruding in the vertical direction from the upper surface of the engaging side body 141, and the engaging side while protruding obliquely from the upper surface of the engaging side body 141 It includes an engaging side inclined surface 147 that is connected to the end of the vertical surface 146, as shown in Figure 5, the engaging side vertical surface 146 and the engaging side inclined surface 147 sequentially a plurality of each other consecutively By being connected to, a tooth shape is achieved.

When the external force transmission member is fixed and the external force transmission side contact portion 133 and the engagement side contact portion 143 are engaged with each other, the engagement side inclined surface 147 and the external force transmission side inclined surface 137 are In the facing direction, the engaging side inclined surface 147 may be rotated while passing over the external force transmitting side inclined surface 137, but in the direction in which the engaging side vertical surface 146 and the external force transmitting side vertical surface 136 face each other The engagement side vertical surface 146 and the external force transmission side vertical surface 136 are in close contact with each other, so that rotation is impossible, so that the engagement member 140 with respect to the external force supply member 120 and the external force transmission member 130 And the rotational direction of the rotating member 150 is determined.

In this embodiment, based on the direction shown in FIG. 5, the engagement with respect to the external force transmission member 130 is clockwise, which is a direction in which the engagement side inclined surface 147 and the external force transmission side inclined surface 137 face each other. Rotation of the member 140 is possible, but the engagement member 140 with respect to the external force transmission member 130 in a counterclockwise direction, in which the engagement side vertical surface 146 and the external force transmission side vertical surface 136 face each other ) Becomes impossible to rotate.

The engaging-side protrusion 142 extends from the bottom surface of the engaging-side body 141 and protrudes a predetermined length, and is inserted into the rotation-side insertion groove 155 described later.

As described above, the engagement side protrusion 142 is inserted into the rotation side insertion groove 155, so that the engagement member 140 and the rotation member 150 are connected and rotated together.

The engagement-side protrusion 142 and the rotation-side insertion groove 155 may be formed at least one, but in this embodiment, the four engagement for stable coupling of the rotation member 150 to the engagement member 140 Side protrusions 142 are formed at equal intervals, and the rotation-side insertion grooves 155 are also formed at equal intervals so as to correspond to the engagement side protrusions 142.

The elastic member 160 is located between the body member 110 and the external force transmission member 130, and is in close contact with the body member 110 and the external force transmission member 130, respectively, and the external force transmission member 130 ) To provide an elastic force, such as a spring may be presented as an example.

In detail, the elastic member 160 so that the upper portion of the elastic member 160 is in close contact with the upper cover 113 of the body, and the lower portion of the elastic member 160 is in close contact with the body 131 of the external force transmission side. As it is disposed, when the elastic member 160 is inserted into the external force supply side body 121, the inner diameter of the coil of the elastic member 160 (when the elastic member 160 is bent is formed in a coil shape that is rotated multiple times, The diameter formed at the center by the rotation) is formed to be relatively large compared to the diameter of the body 121 on the external force supply side.

As illustrated in FIG. 6, when an external force is applied to the external force supply member 120 and the external force transmission member 130 is rotated at a predetermined angle in one direction, the external force transmission member 130 is provided with the external force supply member 120. ) Relative to the external force supply member 120 so that the external force transmission member 130, more precisely, the elastic member 160 in close contact with the external force transmission side body 131 is also compressed. As it approaches, it stores the elastic force.

On the other hand, as illustrated in FIG. 7, when an external force is applied to the external force supply member 120 and the external force transmission member 130 is rotated at a predetermined angle in the other direction, the stored elastic force of the elastic member 160 is restored. The external force transmission member 130 is relatively far from the external force supply member 120, and accordingly, the external force transmission member 130 and the engagement member 140 are engaged with each other.

The rotating member 150 is inserted into the pipe therein and is connected to the engaging member 140 and rotated together with the engaging member 140, the rotational direction by an external force supplied from the external force supply member 120 This is variable.

In detail, the rotating member 150 includes the rotating side body 151, bearings 152, 154, and clamps 147, 157, and in this embodiment, the rotating member 150 includes a spacer 153 ).

In this embodiment, a pair of the clamps 147 and 157 and a pair of the bearings 152 and 154 are installed at a predetermined distance for easy fixing and smooth rotation of the rotating member 150, and The bearings 152 and 154 are respectively defined as a first bearing 152 and a second bearing 154, and the clamps 147 and 157 are defined as a first clamp 147 and a second clamp 157, respectively. Explain.

The rotating side body 151 is formed to have a certain length in the longitudinal direction of the body member 110, and a hole corresponding to the pipe is formed through from the top to the bottom so that at least one pipe is inserted therein. .

The outer side of the rotation-side body 151 is formed with a rotation-side insertion groove 155 recessed in a certain depth from the outer surface to the inside of the engagement side protrusion 142 is inserted, as shown in FIG. The engagement side protrusion 142 is inserted into the rotation side insertion groove 155 so that the engagement side protrusion 142 and the rotation side insertion groove 155 are connected to the engagement member 140 and the rotation member 150 Is rotated together.

Reference numeral 156 is a rotation-side horizontal groove recessed at a predetermined depth along an arc from the outside of the rotation-side body 151, and a second clamp inner projection 158, which will be described later, is inserted into the rotation-side horizontal groove 156 to be inserted into the The position of the second clamp 157 is fixed.

The bearings 152 and 154 are connected to the outside of the rotating side body 151 so that the rotating side body 151 rotates with respect to the body member 110.

In this embodiment, the bearings 152 and 154 are composed of the first bearing 152 and the second bearing 154.

The first bearing 152 is positioned to be close to the upper portion of the rotating side body 151, that is, relatively close to the engaging member 140.

The second bearing 154 is positioned to be spaced apart from the first bearing 152 by a predetermined distance, so as to be closer to the lower portion of the rotating side body 151, that is, relatively distant from the engaging member 140.

When the first bearing 152 and the second bearing 154 are inserted into the rotating side body 151, the inner diameters of the first bearing 152 and the second bearing 154 are the rotating side body ( By being formed to correspond to the outer diameter of 151, the inner ring of the first bearing 152, the inner ring of the second bearing 154, and the rotating side body 151 can be rotated together.

The clamps 147 and 157 fix the positions of the bearings 152 and 154.

In detail, the first clamp 147 is a flat plate having a relatively small thickness compared to an area, but is a donut shape through which the central portion is penetrated, and is formed in a'C' shape in which at least a portion is cut, and the first bearing 152 is It is to prevent the movement of the first bearing 152 by being in contact with the outer surface, which is a side that is relatively close to the engagement member 140.

The second clamp 157 is a flat plate having a relatively small thickness compared to the area, and is a donut shape through which the central portion is penetrated, and is formed in a'C' shape in which at least a portion is cut, and is symmetrical with the first clamp 147. It is to prevent the movement of the second bearing 154 by being in contact with an outer surface that is a side that is relatively far away from the engaging member 140 among the second bearings 154.

The spacer 153 is located between the first bearing 152 and the second bearing 154, one end is in contact with the inner surface of the first bearing 152, the other end is the first 2 is in contact with the inner surface of the bearing 154 to maintain the separation distance between the first bearing 152 and the second bearing 154.

On the other hand, the first clamp 147 has a portion of the first clamp 147 extending a predetermined length in the outer direction so as to be relatively large compared to the outer diameter of the first clamp 147, the first clamp outer projection 148 ) Is formed, and the first clamp outer protrusion 148 is inserted into the body-side horizontal groove 112 constituting the body member 110 to fix the position of the first clamp 147.

In addition, the second clamp 157 is a second clamp inner projection 158 of which a portion of the second clamp 157 protrudes a certain length in the inner direction so as to be relatively smaller than the inner diameter of the second clamp 157. Is formed, the second clamp inner projection 158 is inserted into the rotating side lateral groove 156, the second clamp 157 is fixed to the position.

Then, the rotating member 150 has the first clamp 147, the first bearing 152, the spacer 153, and the second bearing 154 on the outer side of the rotating side body 151. ), the second clamp 157 is sequentially inserted from the top, the first clamp outer protrusion 148 formed in the first clamp 147 is inserted into the body-side horizontal groove 112, the The second clamp 157 formed in the second clamp 157 is inserted into the rotary side lateral groove 156, so that the first clamp 147 with respect to the rotating body 151 and the first The position of the first bearing 152, the spacer 153, the second bearing 154, and the second clamp 157 is fixed, and the rotating side body 151 is the first bearing 152 ) And the second bearing 154 make it possible to rotate in the arc direction with respect to the central axis of the longitudinal direction of the rotating side body 151.

When the one-way rotation unit 100 applied to the industrial rack system is made as described above, when the external force supply member 120 is rotated at an angle in one direction by an external force applied to the external force supply member 120 , After the external force transmission side side protrusion 132 inserted into the side through hole 119 passes through the inclined surface 127 at the second seating surface 128 and then seats on the first seating surface 126 As the external force transmission member 130 is moved toward the external force supply member 120, the elastic member 160 positioned on the external force transmission member 130 is compressed by the movement of the external force transmission member 130. As the elastic force is stored and the external force transmission-side contact portion 133 is spaced apart from the engagement-side contact portion 143, the external force transfer-side contact portion 133 and the engagement-side contact portion 143 are released. , Accordingly, the engaging member 140 and the rotating member 150 connected to the engaging member 140, more precisely, the rotating side body 151 into which the pipe is inserted can be freely rotated in both directions.

On the other hand, when the external force supply member 120 is rotated at a predetermined angle in the other direction by an external force applied to the external force supply member 120, the elastic force of the compressed elastic member 160 is restored while the elastic member 160 is restored. Is returned to the original position, the second seating surface after the external force transmission side side protrusion 132 passes through the inclined surface 127 from the first seating surface 126 by returning to the original position of the elastic member 160. While seated on the 128, the external force transmission member 130 is moved toward the engagement member 140, and by the movement of the external force transmission member 130, the external force transmission side contact portion 133 and the engagement side contact The rotating member 150 is connected to the engaging member 140 and the engaging member 140, and more precisely, the rotating side body 151 into which the pipe is inserted is transmitted to the external force. It can be rotated in a predetermined direction by the member 130.

As described above, the one-way rotation unit 100 applied to the industrial rack system is applied to the industrial rack system and the body member 110, the external force supply member 120, and the external force transmission member 130 are applied. And, including the engaging member 140, the rotating member 150, the external force supply member 120, the external force transmission member 130, the engaging member 140, and the rotating member ( 150) is disposed inside the body member 110, and when the external force supply member 120 is rotated at a certain angle in one direction by an external force applied to the external force supply member 120, the external force transmission member 130 Is moved so as to be relatively close to the external force supply member 120, the external force transmission member 130 and the engaging member 140 are spaced apart, and the external force transmission member 130 and the engaging member 140 are separated from each other. By this, the engagement between the external force transmission member 130 and the engagement member 140 is released, so that the engagement member 140 and the rotation member 150 can be freely rotated in both directions, and the external force supply member When the external force transmission member 130 is rotated at a predetermined angle in the other direction by the external force applied to the 120, the external force transmission member 130 is moved to be relatively far away from the external force supply member 120 to transmit the external force The member 130 and the meshing member 140 are engaged, and the rotational direction of the meshing member 140 is limited by the meshing of the external force transmitting member 130 and the meshing member 140, and accordingly, the The engaging member 140 and the rotating member 150 are rotated in a predetermined direction, so that a moving object can be moved and rotated in a predetermined direction in a predetermined direction in a short time while being applied to the industrial rack system. do.

Hereinafter, a one-way rotating unit applied to an industrial rack system according to another embodiment of the present invention will be described with reference to the drawings. In carrying out such a description, a description overlapping with the contents already described in the first embodiment of the present invention described above is replaced with it, and will be omitted here.

13 is a perspective view of a one-way rotation unit applied to an industrial rack system according to a second embodiment of the present invention, viewed from above, and FIG. 14 is a one-way rotation applied to an industrial rack system according to a second embodiment of the present invention The unit is a front view when viewed from the front, and FIG. 15 is a view showing a state in which a one-way rotating unit applied to an industrial rack system according to a second embodiment of the present invention is used in an industrial rack system.

13 to 15, the one-way rotation unit 200 applied to the industrial rack system according to the present embodiment includes a body member 210, an external force supply member 220, an external force transmission member, and an engagement member And, it includes a rotating member 250.

The external force supply member 220 is inserted and connected to the body member 210, and external force is supplied from the outside by an operator or a tool, and includes an external force supply side body and a side through hole, and the external force supply side body includes external force The supply-side expansion body 222 and the external force applying body 229 are formed.

In the present embodiment, an external force supply connection hole 218 through which the external force supply body 50 is connected, such as a tension spring, is further formed through the circular force application body 229.

The external force supply connecting hole 218 has the same center as the external force applying body 229 and is formed through a circular shape of a certain diameter, and the external force supply body 50 connected to the external force supply connecting hole 218 ) To operate the external force applying body 229 to engage the external force transmission member and the engagement member with each other, or to disengage the engagement of the external force transmission member and the engagement member engaged with each other.

In the present embodiment, as an example, the engagement is released by the external force supply body 50 in the state where the external force transmission member and the engagement member are engaged with each other.

Reference number 10 is a main table on which a moving object is placed, and reference number 20 is connected to a one-way rotating unit 200 applied to the industrial rack system and is elevated in the vertical direction of the main table 10 to move the main table 10 ) Can be located on the side of the auxiliary table 20, the reference number 30 is a rack gear that is formed to be long in the vertical direction in the lower portion of the main table 10, the reference number 40 is applied to the industrial rack system It is connected to the one-way rotating unit 200, and is engaged with the rack gear 30 and moved in the longitudinal direction of the rack gear 30, thereby unidirectional rotating unit 200 and the auxiliary applied to the industrial rack system A pinion gear for elevating the table 20, reference numeral 60 is a one-sided end fixture connected to one end of the external force supply 50 to fix the position of one end of the external force supply 50 .

When the external force transmitting member and the engaging member constituting the one-way rotating unit 200 applied to the industrial rack system are engaged, an operator rotates the pinion gear 40 clockwise based on the direction shown in FIG. 15. When rotating, the one-way rotating unit 200 and the auxiliary table 20 applied to the industrial rack system connected to the pinion gear 40 so that the auxiliary table 20 is located on the side of the main table 10 This rises, and at this time, the external force supply body 50 connected to the external force supply connection hole 218 is also tensioned to store elastic force.

When the one-way rotating unit 200 and the auxiliary table 20 applied to the industrial rack system connected to the pinion gear 40 are raised and the auxiliary table 20 is located on the side of the main table 10 When the elastic force is restored, the tensioned external force supply body 50 rotates the external force supply member 220 at a predetermined angle in the clockwise direction, and the external force transmission member and the external force are transmitted by the external force supply member 220 rotated at an angle. As the engagement member is spaced apart, the engagement between the external force transmission member and the engagement member is released, and thus the engagement member and the rotation member 250 can be freely rotated in both directions, thereby being applied to the industrial rack system. The directional rotation unit 200 and the auxiliary table 20 are automatically moved in the lower direction of the main table 10.

One or more external force supply body connection holes 218 may be formed, but as in the present embodiment, it is preferable that they are respectively formed in the external force applying body 229.

In the present embodiment, the external force applying body 229 is tensioned at the lower portion of the main table 10 and installed to release the engagement between the external force transmitting member and the engaging member, but this is only one example, and the external force is applied It is also possible that the external force transmitting member and the engaging member are engaged with each other by being installed so that the tensile direction of the sieve 229 is opposite to each other by the elastic force of the external force applying body 229.

The external force supply connection hole 218 is formed in the external force supply member 220 constituting the one-way rotation unit 200 applied to the industrial rack system as described above, and the external force supply connection hole 218 is formed. By connecting the external force supply body 50 to the one-way rotating unit 200 applied to the industrial rack system by the elastic force of the external force supply body 50 even if there is no external force using a worker or a tool to be returned to the original position It becomes possible.

 Although the present invention has been shown and described in relation to a specific embodiment, those skilled in the art may vary the present invention within the scope and spirit of the present invention described in the following utility model registration claims. You can see that it can be modified and changed. However, it is intended to clarify that all of these modifications and variations are included within the scope of the present invention.

According to the one-way rotation unit applied to the industrial rack system according to an aspect of the present invention, an external force supply member, an external force transmission member, an engagement member, and a rotation member are disposed inside the body member and applied to the external force supply member Since the engaging member and the rotating member are rotated in a predetermined direction by an external force, a simple structure can be achieved while rotating and moving a moving object in a predetermined direction for a short time in a state applied to the industrial rack system. It is said that the availability is high.

100: one-way rotating unit applied to an industrial rack system
110: body member 111: body side body
112: body side horizontal groove 113: body side upper cover
115: body side lower cover 117: body side vertical groove
120: external force supply member 121: external force supply side body
119: side through hole 123: flat
124: first side 124: second side
126: first seating surface 127: slope
128: second seating surface 130: external force transmission member
131: external force transmission side body 132: external force transmission side side projection
133: external force transmission side contact portion 134: external force transmission side fixing projections
140: engaging member 141: engaging side body
142: engaging side projection 143: engaging side contact portion
147: first clamp 150: rotating member
151: rotating body 152: first bearing
153: spacer 154: second bearing
155: insertion groove on the rotation side 156: horizontal groove on the rotation side
157: second clamp 160: elastic member

Claims (5)

A plurality of pipes are connected to each other by metal joints are applied to an industrial rack system capable of constructing an industrial structure, and as being capable of rotating at least one pipe inserted therein among the plurality of pipes,
A body member constituting the outer frame;
An external force supply member connected to the body member and supplied with an external force;
It is connected to the external force supply member to transmit the external force supplied by the external force supply member, and when the external force supply member is rotated at a certain angle in one direction by the external force, it moves to be relatively close to the external force supply member, and supplies the external force An external force transmission member moved when the member is rotated at a predetermined angle in the other direction by the external force to move relatively away from the external force supply member;
An engagement member formed in a form of engaging with the external force transmission member to receive the external force transmitted from the external force transmission member; And
It includes; a rotating member that is inserted into the pipe therein and is connected to the engaging member and rotated together with the engaging member, the rotational direction of which is variable by an external force supplied from the external force supply member;
The external force supply member, the external force transmission member, the engagement member, and the rotating member are disposed inside the body member,
When the external force supply member is rotated at a certain angle in one direction by an external force applied to the external force supply member, the external force transmission member is moved to be relatively close to the external force supply member so that the external force transmission member and the engagement member are spaced apart. , The separation of the external force transmission member and the engagement member by the separation of the external force transmission member and the engagement member is released, so that the engagement member and the rotating member can be freely rotated in both directions,
When the external force transmission member is rotated at a certain angle in the other direction by an external force applied to the external force supply member, the external force transmission member is moved to be relatively far away from the external force supply member so that the external force transmission member and the engagement member are engaged. , The rotational direction of the meshing member is limited by the meshing of the external force transmitting member and the meshing member, and accordingly, the meshing member and the rotating member can be rotated in a predetermined direction. One-way rotating unit applied. According to claim 1,
The one-way rotation unit applied to the industrial rack system is
Includes; between the body member and the external force transmission member, the elastic member that is in close contact with the body member and the external force transmission member to provide elastic force to the external force transmission member;
When an external force is applied to the external force supply member to rotate the external force transmission member at a certain angle in one direction, the external force transmission member is relatively close to the external force supply member, and accordingly, the elastic member in close contact with the external force transmission member is also provided. Stores elastic force while being relatively close to the external force supply member,
When an external force is applied to the external force supply member and the external force transmission member is rotated at a predetermined angle in the other direction, the stored elastic force of the elastic member is restored and the external force transmission member is relatively far from the external force supply member, and accordingly A one-way rotating unit applied to an industrial rack system, characterized in that the external force transmitting member and the engaging member are engaged with each other. According to claim 2,
The external force supply member
An external force supply side body connected to the body member and formed in a donut shape through which the central portion passes;
It includes a side through hole formed through the side of the external force supply side body,
The side through hole
A plane formed in a flat shape on the external force supply side body,
A first side surface formed by bending in a direction perpendicular to the plane at one end portion of the plane,
A second side which is formed by bending in a direction perpendicular to the plane so as to face the first side at the other end of the plane, and a second side that is formed to be relatively longer than the first side,
A first seating surface extending parallel to the plane at an end of the first side surface,
A second seating surface extending parallel to the plane at an end of the second side surface and positioned at a different height from the first seating surface,
It includes an inclined surface connecting the first seating surface and the second seating surface,
The external force transmission member
And the external force transmission side body is formed in a donut shape through which the central portion is penetrated and a portion thereof is inserted into the external force supply member,
A side protrusion protruding a certain length from the side of the body of the external force transmitting side, and inserted into the side through hole,
It is formed in the form of a sawtooth (sawtooth) on the bottom surface of the body of the external force transmission side and includes an external force transmission side contact portion that can be in close contact with the engagement member,
The engaging member
Interlocking body formed in the form of a donut through the center,
An engagement side contact portion formed in a sawtooth shape corresponding to the external force transfer side contact portion on an upper surface of the engagement side body, and engaged with the external force transfer side contact portion,
It includes an engaging side projection extending from the bottom surface of the engaging side body protruding a certain length,
When the external force supply member is rotated at a certain angle in one direction by an external force applied to the external force supply member, the external force transmission side side protrusion inserted into the side through hole passes through the inclined surface at the second seating surface, and then the While being seated on the first seating surface, the external force transmitting member is moved toward the external force supply member, and the elastic force stored while the elastic member located on the external force transmitting member is compressed by the movement of the external force transmitting member and the external force is stored. As the transmission-side contact portion is spaced apart from the engagement-side contact portion, the external force transfer-side contact portion and the engagement-side contact portion are disengaged, so that the engagement member and the rotation member connected to the engagement member are free to rotate in both directions. Can,
When the external force supply member is rotated at a predetermined angle in the other direction by an external force applied to the external force supply member, the elastic force of the compressed elastic member is restored and the elastic member is returned to its original position, and the elastic member is returned to its original position. The external force transmitting member is moved toward the engaging member while being seated on the second seating surface after passing through the inclined surface at the first seating surface, and the external force transmitting side side protrusion is moved toward the engaging member, and the external force is transferred by the movement of the external force transmitting member. In the industrial rack system, characterized in that the transmission side contact portion and the engagement side contact portion are engaged, and the engagement member and the rotating member connected to the engagement member can be rotated in a predetermined direction by the external force transmission member. One-way rotating unit applied. The method of claim 3,
The rotating member
A rotating side body into which at least one pipe is inserted,
A bearing that is connected to the outside of the rotating side body to rotate the rotating side body with respect to the body member,
It includes a clamp for fixing the position of the bearing,
On the outer side of the rotation-side body, a rotation-side insertion groove is formed recessed a predetermined depth from the outer side to the inside so that the engagement-side protrusion is inserted,
The one-way rotating unit applied to the industrial rack system characterized in that the engaging member and the rotating member are rotated together by the engaging-side protrusion being inserted into the rotating-side insertion groove so that the engaging-side protrusion and the rotating-side insertion groove are connected. . The method of claim 4,
The body member
The body member further includes a longitudinal groove formed on the inner side of the body member while being inserted in a certain depth and elongated in the longitudinal direction of the body member.
The external force transmission member
It protrudes a predetermined length from the outer surface of the external force transmission side body constituting the external force transmission member, and is spaced apart from the external force transmission side side protrusion and disposed to be relatively closer to the external force transmission side contact portion than the external force transmission side side protrusion. Further comprising a fixing projection on the external force transmission side,
Industrial use characterized in that rotation of the external force transmission member relative to the body member is prevented as the external force transmission side fixing protrusion is inserted into the body side vertical groove and the external force transmission side fixing protrusion and the body side vertical groove are connected. One-way rotating unit applied to rack systems.

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