KR20160071271A - Absorber expansion of the duct unit - Google Patents

Abstract

Disclosed is an expansion absorbing device of a duct unit. According to an embodiment of the present invention, the expansion absorbing device includes: a bellows unit including a bellows housing connected to the surface of a duct unit, transferring a high temperature fluid, to be extended outside the duct unit, and a pair of support brackets extended to the outside while being symmetrical to each other in the bellows housing; a rug connected to a flange extended from the top of the bellows unit; and a stretch connection unit inserted into the rug and of which both ends are combined with the support brackets. Therefore, the present invention is capable of improving workability of workers.

Description

Absorber expansion of the duct unit < RTI ID = 0.0 >

In order to prevent damages of a duct unit due to expansion or contraction of a duct unit to which a high-temperature gas or a fluid is transferred, the expansion / contraction unit is installed to prevent breakage, damage or vibration due to thermal expansion of the duct unit To an expansion absorber for minimizing the occurrence of the expansion.

In general, expansion joints can be used to provide a variety of factors affecting piping, such as thermal expansion of pipelines, ducts, vessels, etc. exposed to ambient temperature when transporting fluids with pressure and temperature through the piping They are installed in preparation for contraction, and they are classified into various types according to their shapes.

For example, when the temperature of the fluid moving to the pipe or the duct is rapidly raised to a high temperature, stress is concentrated at a specific portion where the temperature is elevated. Accordingly, in the case of a pipe or a duct, Or the entire pipe or duct is broken.

An expansion joint is installed to prevent breakage and deformation due to rapid thermal expansion in order to prevent breakage due to thermal expansion at a local position of the pipe or pipe in which such high temperature fluid is moved.

Expansion joints are available in a variety of shapes, such as pipe bands, expansion loops, or link shapes, which are used to minimize damage and deformation of pipes or piping.

In the case of the link type of the expansion joint used in this way, since the unit links having a predetermined length are rotatably connected to each other through the coupling pins, a phenomenon that the unit links protrude more than necessary outward of the duct is generated, A problem that the additional space required by the user is required.

For example, when a duct is installed in a narrow space, a space for installing a link-type expansion joint can not be secured, thereby causing a problem that the duct is installed at a different position or installed in an unstable state.

U.S. Published Patent Application No. US2013 / 0127158A1

Embodiments of the present invention provide an expansion absorber of a duct unit capable of stably absorbing a displacement of a duct unit in which thermal expansion occurs in a specific direction.

According to an aspect of the present invention, there is provided a bellows type air conditioner comprising: a bellows housing communicating with a surface of a duct unit to which a high-temperature fluid is transferred, the bellows housing extending outwardly of the duct unit; A bellows unit comprising a support bracket of a bellows; A lug connected to a flange extending from a top point of the bellows unit, and an expansion joint unit inserted into the lug and having both ends joined to the support bracket.

The lug includes an insertion hole formed for insertion of the expansion joint unit.

And the lug is provided with a bearing unit in which the insertion hole is moved relative to the outer peripheral surface of the expansion joint unit.

The expansion joint unit includes a guide bar inserted in the lug, and the guide bar is inserted into a support bracket provided in the bellows unit.

Wherein the guide bar is formed with a groove into which the ball bearing of the bearing unit is partially inserted so that the ball bearing and the groove are relatively moved when the guide bar is moved up and down and left and right.

The guide bar And a stopper which is provided at both ends with respect to the longitudinal direction to selectively hold the support bracket when the duct unit is expanded in volume.

Wherein the stopper includes: a first stopper positioned at both ends of the support bracket; And a second stopper spaced apart from the first stopper and positioned to face each other.

The support bracket has a first connection arm formed at an upper end thereof with an insertion groove opened toward the guide bar. At both ends of the guide bar, a second connection arm, which is rotatably coupled to the first connection arm via a coupling pin, Is formed.

The first connection arm is inclined at a first inclination angle? 1 toward the first connection arm to limit the rotation angle of the second connection arm to a specific angle.

According to another aspect of the present invention, there is provided an expansion absorber for a duct unit, comprising: a first and a second bellows housing communicating with upper and lower surfaces of a duct unit to which a high-temperature fluid is transferred and extending to the outside of the duct unit; A bellows unit including a pair of support brackets extending outwardly in symmetry with each other in the bellows housing; A lug connected to a flange extending from a top point of the first and second bellows units, a flexible joint unit inserted into the lug and having opposite ends joined to the support bracket; And a connecting member for connecting the first and second bellows housings to each other.

The expansion joint unit includes a guide bar inserted in the lug, and the guide bar is inserted into a support bracket provided in the bellows unit.

The guide bar may further include a stopper provided at both ends of the guide bar to selectively hold the support bracket when the duct unit is expanded in volume.

Embodiments of the present invention can stably damp the thermal expansion of a duct or a pipe through which a high-temperature fluid moves, and can be easily installed even when the space where the duct or the pipe is installed is small, do.

Embodiments of the present invention can be installed on the top, bottom, or sides of the duct and can be used irrespective of uneven thermal expansion of the duct.

1 is a front view of an expansion absorber of a duct unit according to an embodiment of the present invention;
2 is a plan view of an expansion absorber of a duct unit according to an embodiment of the present invention.
3 is a view showing a state in which a bearing unit is coupled to a guide bar in an embodiment of the present invention.
4 is a view showing a state of engagement of first to second connection arms of an expansion absorption device of a duct unit according to another embodiment of the present invention.
5 is a front view showing an expansion absorption apparatus of a duct unit according to another embodiment of the present invention.

An expansion absorbing device for a duct unit according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a front view of an expansion absorber of a duct unit according to an embodiment of the present invention, FIG. 2 is a plan view of an expansion absorber of a duct unit according to an embodiment of the present invention, Fig. 5 is a view showing a state in which the bearing unit is coupled to the guide bar in one embodiment of the present invention.

1 to 3, the expansion absorber 1 of a duct unit according to an embodiment of the present invention is described only for a duct unit, but can be applied to a pipe or other components in which thermal expansion occurs And is not particularly limited to a duct unit.

The expansion absorber 1 of the duct unit includes a bellows unit 100 and a stretch joint unit 200 connected to the bellows unit 100. The bellows unit 100 includes a duct A bellows housing 110 communicating with one side of the unit 10 and extending to the outside of the duct unit 10 and a pair of support brackets 110 extending outwardly in symmetry with each other in the bellows housing 110 120).

The duct unit 10 described in this embodiment has a rectangular parallelepiped shape and a rectangular cross-sectional shape is used, but it should be understood that the shape shown in the drawings can be changed without necessarily being limited thereto.

Since the duct unit 10 is located on the left and right sides of the bellows housing 110 and communicates with the upper surface of the duct unit 10 spaced apart from the bellows housing 110, When moved through the unit 10, a displacement due to thermal expansion is transmitted.

The bellows housing 110 is fixed on the upper surface of the duct unit 10 which is in communication with the interior of the duct unit 10 and is spaced apart from each other and fixed to the pair of connecting members 111, And a pair of covers 112 formed on the upper surface of the connecting member 111 in a hemispherical shape.

Since the connecting member 111 is fixed to the upper surface of the duct unit 10 so that thermal expansion occurs in the inner region of the duct unit 10 and the high temperature fluid is concentrated on the right side of the drawing unit, When the high temperature fluid is concentrated on the left side in the inner area of the duct unit 10, the connecting member and the fixed cover 112 located on the left side of the duct unit 10 are moved upward, And the fixed cover 112 are moved upward.

The bellows housing 110 is thermally expanded toward one of the right and left sides or simultaneously outwardly depending on the position where thermal expansion occurs in the duct unit 10.

The bellows unit 100 includes the bellows housing 110 and the support bracket 120. The support brackets 120 are formed as a pair of bellows housings 110 extending outwardly in a symmetrical state And is formed in an L shape and is fixed to the bellows housing 110 in a state of facing each other.

The expansion joint unit 200 is inserted into the lug 204 and both ends thereof are inserted into the support bracket 120. The lug 204 is connected to a flange extending from the top of the bellows unit 100.

The lug 204 includes an insertion hole 212 having a plate shape and an opening at the center, and a guide bar 210 to be described later is inserted into the insertion hole 212, and a detailed description thereof will be described later.

The lug 204 is fixed at the apex (the highest position) of the cover 112 formed in a hemispherical shape, and the diameter that is opened according to the diameter of the guide bar 210 to be described later is determined.

The guide bar 210 further includes a stopper 214 provided at both ends with respect to the longitudinal direction to selectively hold the support bracket 120 when the duct unit 10 is expanded in volume, The stopper 214 prevents the guide bar 210 from being excessively moved toward a specific direction, thereby preventing breakage and deformation of the guide bar 210, improving durability, and improving the thermal expansion of the duct unit 10 So that stable operation of the equipment to which the duct unit 10 is connected is enabled.

The stopper 214 includes a first stopper 214 positioned at both ends of the support bracket 120 and a second stopper 214b positioned apart from the first stopper 214a and positioned to face each other And the first and second stoppers 214a and 214b are formed in a plate shape and are installed to be spaced apart from both ends of the guide bar 210.

The first and second stoppers 214a and 214b are provided to restrict the excessive movement of the guide bar 210 while directly contacting the first and second stoppers 214a and 214b according to the movement of the guide bar 210, The spacing distance between the first and second stoppers 214a and 214b is adjusted according to the amount of displacement generated due to the displacement.

3, the lug 204 according to another embodiment of the present invention is provided with a bearing unit 300 in which an insertion hole 212 is relatively moved with the outer circumferential surface of a guide bar 210 to be described later, In the bearing unit 300, when the ball bearing is used and the outer circumferential surface of the ball bearing rotating and the outer circumferential surface of the guide bar 210 are relatively moved, the guide bar 210 is moved to the left or right or up / It is possible to prevent the deformation or breakage of the inner circumferential surface of the guide bar 210 or the insertion hole 212 even when the guide bar 210 is rapidly moved in any direction.

The guide bar 210 has a circular cross-section, which is elongated relative to the transverse length of the bellows unit 100 and is inserted into the support bracket 120 at both ends thereof.

The guide bar 210 is formed with a groove portion 210a for partially inserting into a bearing provided in the bearing unit 300 so that when the guide bar is moved in the up and down and right and left directions, the ball bearing and the groove portion 210a move relative to each other The ball bearings are relatively moved along the grooves 210a even when the guide bar 210 is suddenly moved in any of the up, down, left, and right or forward and backward directions. Therefore, the occurrence of deformation due to abrasion and friction due to rolling contact is minimized, so that it can be used stably even when it is used for a long time.

A support bracket and a guide bar according to another embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 4, unlike the above-described embodiment, the support bracket is not a guide bar inserted in the support bracket, but the support bracket and the guide bar are coupled with each other.

The support bracket 120 has a first connection arm 114 formed at an upper end thereof with an insertion groove 112 opened toward the guide bar 210. At both ends of the guide bar 210, And a second connection arm 220 rotatably coupled to the second connection arm 114 via a coupling pin 2 is formed.

The first connection arm 114 is opened to a predetermined shape and depth toward the second connection arm 220 so that the second connection arm 220 is inserted, and the second connection arm 220 is inserted The guide bar 210 can be moved up and down within an open area of the first connection arm 114. [

The support bracket 120 includes a rotation hole 4 having a lower end in a spherical shape and can be easily moved when the guide bar 210 is moved in the forward and backward directions by the rotation hole 4. [ The guide bar 210 can be deformed or deformed without deforming the support bracket 120 even when the guide bar 210 is moved in either the forward, The displacement of the bellows unit 100 due to the thermal expansion of the bellows unit 10 can be absorbed.

The first connection arm 114 is inclined at a first inclination angle? 1 toward the second connection arm 220 to limit the rotation angle of the second connection arm 220 to a specific angle, The angle of inclination is not particularly limited to the angle shown in the drawing, and can be variously changed.

An expansion absorbing device for a duct unit according to another embodiment of the present invention will be described with reference to the drawings.

5, the expansion absorber 1a of the duct unit is connected to the upper and lower surfaces of the duct unit 10 through which the high-temperature fluid is transferred, The bellows unit 100 includes two bellows housings 110a and 110b and a pair of support brackets 120 extending outwardly in symmetry with each other in the first and second bellows housings 110a and 110b. A lug 204 connected to a flange extending from a top point of the first and second bellows housings 110a and 110b and a flexible joint inserted into the lug 204 and having opposite ends joined to the support bracket 120, A unit 200; And a connecting member 400 connecting the first and second bellows housings 110a and 110b to each other.

The bellows unit 100 is installed on the upper and lower surfaces of the duct unit 10 differently from the above embodiments. When the bellows unit 100 is installed, the duct unit 10 is moved The duct unit 10 is displaced in the rightward direction on the basis of the drawing due to rapid thermal expansion in the vertical direction of the duct unit 10 and the expansion and contraction of the duct unit 10 is performed by the expansion joint unit 200, The guide bar 210 is moved to a state shown in the drawing.

Also, since the connecting member 400 is moved together with the guide bar 210 in the longitudinal direction according to the thermal expansion of the duct unit 10, it is possible to stably absorb the displacement due to the thermal expansion.

The duct unit 10 is positioned on the left and right sides of the first and second bellows housings 110a and 110b and is spaced apart from the first and second bellows housings 110a and 110b, .

The first and second bellows housings 110a and 110b are fixed to the upper and lower surfaces of the duct unit 10 which communicate with the inside of the duct unit 10 and are spaced apart from each other, And a pair of covers 112 formed on the upper surface of the connecting member 111 in a hemispherical shape.

Since the connecting member 111 is fixed to the upper surface of the duct unit 10, when thermal expansion occurs in the inner region of the duct unit 10 and the high-temperature fluid is concentrated on the right or left side of the drawing, The connecting member located on the right side of the unit 10 and the fixed cover 112 are moved to one side.

As described above, the first and second bellows housings 110a and 110b are thermally expanded toward one of the right and left sides or simultaneously outwardly depending on the position where the thermal expansion occurs in the duct unit 10.

The bellows unit 100 includes the first and second bellows housings 110a and 110b and the support bracket 120 which are symmetrically opposed to each other in the first and second bellows housings 110a and 110b. And the support bracket 120 is formed in an L shape and fixed to the first and second bellows housings 110a and 110b while facing each other.

The expansion joint unit 200 includes a lug 204 (see FIG. 1) connected to a flange extending from the top of the bellows unit 100 and a lug 204 inserted into the lug 204 and having opposite ends inserted into the support bracket 120 do.

The lug 204 includes an insertion hole 212 having a plate shape and an opening at the center, and a guide bar 210 to be described later is inserted into the insertion hole 212, and a detailed description thereof will be described later.

The lug 204 is fixed at the apex (the highest position) of the cover 112 formed in a hemispherical shape, and the diameter that is opened according to the diameter of the guide bar 210 to be described later is determined.

The guide bar 210 has a circular cross-section, which is elongated relative to the transverse length of the bellows unit 100 and is inserted into the support bracket 120 at both ends thereof.

The guide bar 210 further includes a stopper 214 provided at both ends with respect to the longitudinal direction to selectively hold the support bracket 120 when the duct unit 10 is expanded in volume, The stopper 214 prevents the guide bar 210 from being excessively moved toward a specific direction, thereby preventing breakage and deformation of the guide bar 210, improving durability, and improving the thermal expansion of the duct unit 10 So that stable operation of the equipment to which the duct unit 10 is connected is enabled.

The stopper 214 includes a first stopper 214a positioned at both ends of the support bracket 120 and a second stopper 214b spaced apart from the first stopper 214a and positioned to face each other And the first and second stoppers 214a and 214b are formed in a plate shape and are installed to be spaced apart from both ends of the guide bar 210.

The first and second stoppers 214a and 214b are provided to restrict the excessive movement of the guide bar 210 while directly contacting the first and second stoppers 214a and 214b according to the movement of the guide bar 210, The spacing distance between the first and second stoppers 214a and 214b is adjusted according to the amount of displacement generated due to the displacement.

Since both ends of the connecting member 400 are connected to the cover 112 provided in the spaced bellows unit 100, the connecting member 400 stably transfers the displacement of the expansion joint unit 200 according to the thermal expansion of the duct unit 10 Even when a rapid thermal expansion occurs in the duct unit 10, it can be stably transmitted to improve the durability of the expansion joint unit 200.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

10: Duct unit
100: Bellows unit
110: bellows housing
112: insertion groove
114: first connection arm
120: support bracket
200: Expansion joint unit
202: Flange
210: Guide bar
210a:
212: insertion hole
214: Stopper
214a, 214b: First and second stoppers
220: second connection arm
300: Bearing unit
400: connecting member

Claims (12)

A bellows housing having a bellows housing communicating with one side of a duct unit to which a high temperature fluid is transferred and extending to the outside of the duct unit and a pair of supporting brackets extending outwardly in symmetry with each other in the bellows housing; ; And
A lug connected to a flange extending from a top point of the bellows unit; and an expansion joint unit inserted into the lug and having both ends joined to the support bracket. The method according to claim 1,
Preferably,
And an insertion hole formed to allow the expansion joint unit to be inserted. The method according to claim 1,
In the lug,
And a bearing unit in which relative movement with the outer peripheral surface of the expansion joint unit is formed in the insertion hole. The method according to claim 1,
Wherein the expansion joint unit comprises:
And a guide bar inserted in the lug,
The guide bar
And both ends thereof are inserted into a support bracket provided in the bellows unit, respectively. The method according to claim 3 or 4,
The guide bar
Wherein a groove is formed in the bearing of the bearing unit so that the ball is partially inserted into the bearing, and when the guide bar is moved in the up, down, left, and right directions, the ball bearing and the groove are relatively moved with respect to each other. The method according to claim 1 or 4,
The guide bar
Further comprising: a stopper provided at each end of the duct unit, the stopper being selectively engaged with the support bracket when the duct unit is expanded in volume. The method according to claim 6,
The stopper
A first stopper positioned at both ends of the support bracket;
And a second stopper spaced apart from the first stopper and positioned to face each other. The method according to claim 1,
A first connection arm having an insertion groove opened toward the guide bar is formed at an upper end of the support bracket,
And a second connection arm rotatably coupled to the first connection arm via a coupling pin is formed at both ends of the guide bar. 9. The method of claim 8,
Wherein the first connection arm comprises:
Wherein the second connecting arm is inclined at a first inclination angle (? 1) toward the second connecting arm so as to restrict the rotation angle of the second connecting arm to a specific angle. A first and a second bellows housing communicating with upper and lower surfaces of a duct unit to which a high temperature fluid is transferred and extending to the outside of the duct unit; A bellows unit including a pair of support brackets;
A lug connected to a flange extending from a top point of the first and second bellows units, a flexible joint unit inserted into the lug and having opposite ends joined to the support bracket; And
And a connecting member for connecting the first and second bellows housings to each other. 11. The method of claim 10,
Wherein the expansion joint unit comprises:
And a guide bar inserted in the lug,
The guide bar
And both ends thereof are inserted into a support bracket provided in the bellows unit, respectively. 11. The method of claim 10,
The guide bar
And a stopper provided at both ends to selectively hold the support bracket when the duct unit is expanded in volume.

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