KR20200080623A - Pipe mounting apparatus - Google Patents

Abstract

The present invention relates to a flow path fixing device, and an object of the present invention is to provide a flow path fixing device that enables a stable assembly process and a fixed structure to be realized by effectively preventing a deviation from an in-place position during an assembly process while having a simple structure.

Description

Euro mounting apparatus

The present invention relates to a flow path fixing device, and more particularly, to a flow path fixing device including a structure for stably fixing a pipe-shaped flow path provided in a cooling module including a heat exchanger in an assembly process.

In general, various air conditioning systems and cooling systems are installed in vehicles. In general terms, the air conditioning system includes air conditioning and heating modules for controlling air temperature, humidity, etc. in an indoor space where a vehicle occupant is present, and the cooling system includes modules for cooling devices such as engines and motors from overheating. . These various modules are configured to implement desired cooling, heating, and cooling operations by transferring heat while circulating a heat exchange medium such as a refrigerant and cooling water.

Such an air conditioning or cooling system includes a variety of heat exchangers. Among these heat exchangers, a heat exchange medium (for example, refrigerant, coolant, oil, etc.) to be cooled is distributed, and air is blown outside to cool the heat exchange medium. There are air-cooled heat exchangers. In the case of an air-cooled heat exchanger, cooling may be performed by a running wind generated by natural driving, but in general, a fan is provided in the heat exchanger for forcibly blowing air. In this way, since many parts such as a heat exchanger and a fan are often provided in a set, production is performed in a modular form by combining a heat exchanger and a fan shroud in a frame portion for convenience in the production process. As such, assemblies such as a heat exchanger, a fan shroud, and a frame portion are commonly referred to as cooling modules.

Of course, in the heat exchanger included in the cooling module, of course, a flow path in the form of a pipe or hose is provided to distribute the heat exchange medium. At this time, considering the arrangement of the cooling module or the convenience of installation, the flow path provided in the heat exchanger is bent in an appropriate direction in advance to be fixed to the frame portion. 1 shows an exploded perspective view of a conventional flow path fixing device, FIG. 2 shows an exploded perspective view of a conventional flow path fixing device, and FIG. 3 shows an assembled perspective view of a conventional flow path fixing device. 1 to 3, the flow path fixing device 100 ′ provided in the conventional cooling module 500 includes a support portion 150 ′ and a support portion 150 ′ protruding from the frame portion 550. It includes a bracket 110' coupled to the protruding surface of the. At this time, the bracket 110' includes a flat part 111' that is interviewed and coupled to the support part 150', and a bent part 112' connected to the flat part 111' and holding and supporting the flow path 515. .

Conventionally, a coupling bolt 115b', which is coupled through the flat plate portion 111' and the support portion 150', was used to couple the bracket 110' to the support portion 150'. However, in the process of screwing the coupling bolt 115b', the flat plate portion 111' had a problem in that the bracket 110' rotates from a fixed position due to interference during the process. When the flow path fixing device 100' is assembled in a state in which the bracket 110' is rotated from the fixed position, the bent portion 112' formed in a shape that fits the outer surface of the flow path 515 also deviates from the fixed position. , Therefore, the bent portion 112' disposed in the wrong position puts pressure on the flow path 515, thereby causing damage such as bending of the flow path 515. In addition, the fixing itself becomes unstable because the parts are fixed in a misaligned state, which causes unnecessary vibration and causes fatigue damage and noise.

As a technology for a bracket structure for firmly supporting a heat exchanger in the form of a pipe, Korean Patent Publication No. 2007-0014222 ("Support bracket for heat exchangers formed of aluminum pipes", 2007.01.31, hereinafter'Prior literature') have. In the prior literature, the support structure is composed of a combination of the upper bracket and the lower bracket, and includes a locking pin for fixing the pipe to a caulking type. In the case of forming a support structure as an assembling assembly of a plurality of parts as in the prior literature, it will be possible to realize a stable coupling by applying a fixing force in various directions and structures. However, as the number of parts increases, the number of assembly steps increases, productivity decreases, and structural complexity increases, resulting in poor space utilization, and thus there is no effectiveness in applying the structure to the flow path fixing device as in the present invention.

1. Korea Patent Publication No. 2007-0014222 ("Support bracket for heat exchangers formed of aluminum pipes", 2007.01.31)

Therefore, the present invention has been devised to solve the problems of the prior art as described above, and the object of the present invention is to achieve a stable assembly process and a fixed structure by effectively preventing deviation from the position in the assembly process while having a simple structure. It is to provide a flow path fixing device to enable.

The flow path fixing device 100 of the present invention for achieving the above object is a flow path fixing device 100 for fixing the flow path 515 in the form of a pipe extending in one direction, the support coupling hole 155 is formed The supporting part 150; A bracket 110 extending in a direction perpendicular to the extending direction of the flow path 515 to hold and support the flow path 515, and coupled with the support portion 150; A coupling bolt 115b that penetrates the bracket 110 and is screwed with the support part coupling hole 115 to join the bracket 110 and the support part 150; To prevent rotation of the bracket 110 when the coupling bolt 115b is screwed, rotation is prevented from protruding from the bracket 110 or the support part 150 in a direction to limit the rotation of the bracket 110 Way; It may include.

At this time, the anti-rotation means may be a locking portion 113 that is arranged at the opposite end of the bracket 110 to hold and support the flow path 515 to be bent and disposed on the supporting portion 150. Also, at this time, the locking portion 113 may be formed in a shape corresponding to the shape of the outer surface of the support portion 150. In addition, the locking portion 113 may be vertically bent.

In addition, the anti-rotation means may be a protrusion 151 that protrudes from one side of the support part 150 in the protruding direction of the support part 150 so that the side end of the bracket 110 is caught and supported. At this time, a plurality of protrusions 151 may be formed on a region corresponding to a portion other than the portion holding and supporting the flow path 515 of the bracket 110. In addition, at this time, a plurality of the protrusions 151 may be arranged in a direction perpendicular to the extending direction of the flow path 515. Specifically, the protruding portion 151, any one of the protruding portions 151 is formed at a position corresponding to the opposite end of the bracket 110 to hold and support the flow path 515, and the other protruding portion ( 151) may be formed in a position in close contact with the portion to hold and support the flow path 515 of the bracket 110.

In addition, the rotation preventing means, the guide projection 152 is formed to protrude in the protruding direction of the support portion 150 on the protruding surface of the support portion 150, the guide projection is formed in the form of a hole on the bracket 110 A guide protrusion insertion hole 114 into which 152 is inserted may be further included. At this time, the flow path fixing device 100, when the bracket 110 and the support portion 150 is coupled, the bracket 110 and the support portion by the guide projection insertion hole 114 and the guide projection 152 150 may be guided and aligned.

In addition, the support part 150 is formed to protrude in an area corresponding to the position where the flow path 515 passes, and the support part coupling hole 155 may be formed on the protruding surface. At this time, the bracket 110 is connected to the flat portion 111 and the flat plate portion 111 in which the bracket engaging hole 115 is formed by interviewing the protruding surface of the support portion 150, and the flow path 515 It may be bent in a shape corresponding to the outer surface may include a bent portion 112 for holding and supporting the flow path.

In addition, the flow path 515 may be a heat exchange medium flow path through which the heat exchange medium is introduced or discharged in the heat exchanger 510 through which the heat exchange medium is distributed. At this time, the flow path fixing device 100, the heat exchanger 510, the fan shroud 520 and the heat exchanger 510 are stacked and disposed, the heat exchanger 510 and the fan shroud 520 It is formed on a cooling module 500 including a frame portion 550 that is coupled and supported, and the support portion 150 is formed to protrude in an area corresponding to a position where the passage 515 passes on the frame portion 550. In addition, the frame portion 550 may be a radiator tank portion.

According to the present invention, in the flow path fixing device for fixing the flow path of the cooling module in place, there is a great effect of effectively preventing the flow path fixing device from rotating due to interference in an assembly process using screw coupling. In addition, as the prevention of rotation of the flow path fixing device is effectively performed, there is an effect of fundamentally excluding problems such as bending of the flow path or bending out of a fixed position due to rotation of the flow path fixing device. Furthermore, the assembly of the flow path fixing device and the flow path in a well-aligned position forms a stable fixing structure, and problems such as fatigue damage and noise caused by undesired vibration when leaving the fixed position are also inherent. It can be excluded, and in the long term, an effect of improving the durability of the module itself can be obtained.

In addition, according to the present invention, there is an effect that the structure to be added separately is minimized in order to realize such an anti-rotation structure. That is, according to the present invention, there is an effect of effectively preventing rotation without increasing the number of assembly steps and the number of parts.

1 is a conventional flow path fixing device.
Figure 2 is an exploded perspective view of a conventional flow path fixing device.
Figure 3 is an assembled perspective view of a conventional flow path fixing device.
Figure 4 is an exploded perspective view of a first embodiment of the flow path fixing device of the present invention.
Figure 5 is an assembled perspective view of a first embodiment of the flow path fixing device of the present invention.
Figure 6 is an exploded perspective view of a second embodiment of the flow path fixing device of the present invention.
7 is an assembled perspective view of a second embodiment of the flow path fixing device of the present invention.
8 is an exploded perspective view of a third embodiment of the flow path fixing device of the present invention.
9 is an assembled perspective view of a third embodiment of the flow path fixing device of the present invention.

Hereinafter, a flow path fixing device according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

Basic configuration of the flow path fixing device of the present invention

The flow path fixing device 100 of the present invention is for fixing a pipe-shaped flow path 515 extending in one direction, and includes a support portion 150 and a bracket 110 that are screwed by a coupling bolt 115b. In more detail, the support part 150 has a support part coupling hole 155 formed therein, and the bracket 110 extends in a direction perpendicular to the flow direction of the flow passage 515 to hold the flow passage 515. As a supporting role, it is combined with the supporting part 150. At this time, the coupling bolt 115b penetrates through the bracket 110 and is screwed with the supporting portion coupling hole 115 to join the bracket 110 and the supporting portion 150.

As such, in the process of screwing the support part 150 and the bracket 110, the coupling bolt 115b rotates and contacts and interferes with the bracket 110, so that the bracket 110 is coupled to the coupling bolt 115b. ), and often rotates together. Accordingly, there have been various problems, such as the deformation caused by the concentration of stress in the flow path 515 because the bracket 110 deviates from the fixed position. The flow path fixing device 100 of the present invention is to solve this problem, that is, the flow path fixing device 100, to prevent rotation of the bracket 110 when the coupling bolt 115b is screwed, the The bracket 110 or the support portion 150 to include a rotation preventing means protruding in a direction to limit the rotation of the bracket 110.

At this time, the support part 150 may be formed of any separate part, but is preferably made to protrude in an area corresponding to a position where the passage 515 passes from other larger and more stable parts for stable fixing. Of course, in this case, the support part coupling hole 155 is formed on the protruding surface. In addition, at this time, the bracket 110, the flat surface portion 111 and the flat plate portion 111 is formed and the bracket engaging hole 115 is interviewed on the protruding surface of the support portion 150 is connected to the flow path 515 It may be bent in a shape corresponding to the outer surface of the bent portion to support the grab to support the flow path (112).

In addition, the flow path 515 fixed by the flow path fixing device 100 may be a heat exchange medium flow path through which the heat exchange medium is introduced or discharged in the heat exchanger 510 through which the heat exchange medium flows. That is, in this case, the flow path fixing device 100 includes the heat exchanger 510, the fan shroud 520 disposed in a stack with the heat exchanger 510, the heat exchanger 510, and the fan shroud 520. It may be formed on the cooling module 500 including a frame portion 550 to support the coupling, in this case, the support portion 150, the frame portion 550 corresponds to the position where the flow path 515 passes It may be formed in a form that protrudes in the region. In other words, the frame part 550 may be a tank part of a radiator generally included in the cooling module 500, but of course, the present invention is not limited thereto. That is, since the support part 150 may be formed on any part as long as it is suitable for fixing the flow passage 515, the frame part 550 may be a radiator tank part, but is not limited thereto.

Hereinafter, a specific configuration of the flow path fixing device 100 of the present invention will be described through various embodiments, but the following embodiments are examples in which the flow path fixing device 100 is formed on the cooling module 500 as described above. . Of course, the present invention is not limited to this, and the flow path fixing device 100 may be provided in a device other than a cooling module, and may be variously modified within a range including the technical idea of the present invention. to be.

Various embodiments of the flow path fixing device of the present invention

4 is an exploded perspective view of a first embodiment of the flow path fixing device of the present invention, and FIG. 5 is an exploded perspective view of a first embodiment of the flow path fixing device of the present invention. 4 and 5, the flow path fixing device 100 of the present invention includes a bracket 110 and a support portion 150 similarly to the prior art, but further comprises a rotation preventing means.

The rotation preventing means, in order to prevent rotation of the bracket 110 when the coupling bolt 115b is screwed, a direction to limit the rotation of the bracket 110 from the bracket 110 or the support part 150 It is a structure that is formed to protrude. In the first embodiment to be described first, the anti-rotation means is formed on the bracket 110, and in the second embodiment to be described later, the anti-rotation means is formed on the support 150.

4 and 5, in the first embodiment, the rotation preventing means is formed as a locking portion 113 formed in the bracket 110. The locking portion 113, the opposite end of the bracket 110 to hold and support the flow path 515 is formed to be bent and is disposed on the supporting portion 150. That is, the end of the flat plate portion 111 is bent to form the locking portion 113. At this time, the locking portion 113 is a shape corresponding to the outer surface shape of the support portion 150, more specifically, it is preferable that the vertical bending. As described above, when screwing the coupling bolt 115b in the state in which the engaging portion 113 is hung on the supporting portion 150, even if the bracket 110 receives a force to rotate due to interference, the engaging portion ( 113) can be effectively prevented from rotating the bracket 110 by the structure hanging on the support 150.

6 shows an exploded perspective view of a second embodiment of the flow path fixing device of the present invention, and FIG. 7 shows an exploded perspective view of a second embodiment of the flow path fixing device of the present invention. In the second embodiment, as briefly mentioned above, the anti-rotation means is formed on the support 150. In more detail, in the second embodiment, the anti-rotation means is a protrusion 151 formed on the support 150, the protrusion 151 is the support 150 so that the side end of the bracket 110 is supported. It is made of a form that is protruding from the protruding direction of the support portion 150 from one side of the.

At this time, when the protruding surface of the support portion 150 has a smaller area than the flat plate portion 111 of the bracket 110, the protruding portion 151 is the projecting direction of the support portion 150 as it is from the support portion 150 If protruding into the invasion of the position of the bracket 110, rather, the bracket 110 may not be placed in the correct position. Therefore, in this case, the protrusions 151 are arranged to be spaced apart at a predetermined distance in the planar direction of the protrusion surface of the support 150, so that the protrusions 151 are positioned when the bracket 110 is placed in place. It is preferable that the side end of the bracket 110 is accurately contacted.

On the other hand, if the protrusion 151 is formed at a position where the passage 515 passes, it will interfere with the passage 515, so that the protrusion 151 (when the bracket 110 is placed in place) It is preferable that the bracket 110 is formed on an area corresponding to a portion other than the part holding and supporting the flow path 515, that is, an area corresponding to the flat plate 111.

In addition, in order to stably limit the rotation of the bracket 110, as shown in FIGS. 6 and 7, a plurality of protrusions 151 are perpendicular to the direction in which the flow path 515 extends. Can be arranged. More preferably, in order to realize the most stable structure with the smallest number, any one of the protrusions 151 is formed at a position corresponding to the opposite end of the bracket 110 holding and supporting the flow path 515 , Another one of the protrusions 151 may be made to be formed in a position in close contact with the portion to hold and support the flow path 515 of the bracket 110.

Meanwhile, the rotation preventing means may include both the configuration of the first embodiment illustrated in FIGS. 4 and 5 and the configuration of the second embodiment illustrated in FIGS. 6 and 7. That is, the flow path fixing device 100 may include both the locking portion 113 formed on the bracket 110 and the protrusion 151 formed on the support portion 150.

8 is an exploded perspective view of a third embodiment of the flow path fixing device of the present invention, and FIG. 9 is an exploded perspective view of a third embodiment of the flow path fixing device of the present invention. The third embodiment of the flow path fixing device of the present invention, in the flow path fixing device 100 of the present invention as described above, the bracket 110 in the process of disposing the bracket 110 on the support portion 150 ) Includes a structure to guide so that it can be placed more smoothly in place.

The guiding structure of the third embodiment includes a guiding protrusion 152 and a guiding protrusion insertion hole 114 as shown. The guide protrusion 152 is formed to protrude in the protruding direction of the support portion 150 on the protruding surface of the support portion 150, the guide protrusion insertion hole 114 is formed in a hole shape on the bracket 110 The guide projection 152 is inserted.

When the flow path fixing device 100 includes the guide structure as described above, when the bracket 110 and the support portion 150 are coupled, the guide protrusion insertion hole 114 and the guide protrusion 152 are used. The bracket 110 and the support 150 can be guided and aligned. In the absence of the guiding structure, it is inconvenient to adjust the positions of the bracket coupling hole 115 and the support coupling hole 155 in the process of assembling the bracket 110 to the support portion 150. However, when the guide structure is formed, when the guide protrusion 152 is inserted into the guide protrusion insertion hole 114, the positions of the bracket coupling hole 115 and the support coupling hole 155 are naturally aligned. In the assembly process, user convenience can be maximized.

8 and 9 are shown as such a guide structure is further provided in the first embodiment, but of course, the present invention is not limited thereby, and the guide structure may be further provided in the second embodiment. Various changes are possible.

The present invention is not limited to the above-described embodiments, and of course, the scope of application is various, and anyone who has ordinary knowledge in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications are possible.

100: euro fixing device 110: bracket
111: flat plate portion 112: bent portion
113: engaging portion 114: guide projection insertion hole
115: flat plate coupling hole 115b: coupling bolt
150: support 151: protrusion
152: guide projection 155: support coupling hole
500: cooling module
510: heat exchanger 515: Euro
520: fan loud 550: frame section

Claims (15)

A flow path fixing device 100 for fixing a pipe-shaped flow path 515 extending in one direction,
A support part 150 in which the support part coupling hole 155 is formed;
A bracket 110 extending in a direction perpendicular to the extending direction of the flow path 515 to hold and support the flow path 515, and coupled with the support portion 150;
A coupling bolt 115b that penetrates the bracket 110 and is screwed with the support part coupling hole 115 to join the bracket 110 and the support part 150;
In order to prevent rotation of the bracket 110 when the coupling bolt 115b is screwed, rotation is prevented from protruding from the bracket 110 or the support 150 in a direction to limit the rotation of the bracket 110 Way;
Euro fixing device comprising a.
According to claim 1, The anti-rotation means,
A flow path fixing device, characterized in that the opposite end of the bracket 110 to hold and support the flow path 515 is a bent portion 113 that is bent and disposed on the support portion 150.
According to claim 2, The engaging portion 113,
A flow path fixing device characterized in that the support portion 150 is formed in a bending shape corresponding to the outer surface shape.
According to claim 3, The engaging portion 113,
Flow path fixing device characterized in that the vertical bending is formed.
According to claim 1, The anti-rotation means,
A flow path fixing device, characterized in that the protruding portion 151 is formed to protrude in the protruding direction of the support portion 150 from one side of the support portion 150 so that the side end of the bracket 110 is caught and supported.
The method of claim 5, wherein the projection (151),
A plurality of flow path fixing device, characterized in that formed in a plurality of regions corresponding to the portion other than the portion to hold and support the flow path 515 of the bracket 110.
The method of claim 6, wherein the protrusion (151),
A plurality of flow path fixing device, characterized in that arranged in a direction perpendicular to the extending direction of the flow path (515).
The method of claim 6, wherein the protrusion (151),
Any one of the protrusions 151 is formed at a position corresponding to the opposite end of the bracket 110 to hold and support the flow path 515,
Another one of the protruding portion 151 is a flow path fixing device, characterized in that formed in a position in close contact with the portion to hold and support the flow path 515 of the bracket 110.
According to claim 2 or 5, wherein the rotation preventing means,
The guide projection 152 is formed to protrude in the protruding direction of the support portion 150 on the protruding surface of the support portion 150,
A guide protrusion insertion hole 114 formed in a hole shape on the bracket 110 and into which the guide protrusion 152 is inserted
Euro fixing device further comprising a.
The method of claim 9, wherein the flow path fixing device 100,
When the bracket 110 and the support part 150 are coupled, the bracket 110 and the support part 150 are guided and aligned by the guide protrusion inserting hole 114 and the guide protrusion 152. Euro fixing device.
The method of claim 1, wherein the support unit 150,
A flow path fixing device characterized in that the flow path (515) is formed to protrude in an area corresponding to the passing position, and the support part coupling hole (155) is formed on the protruding surface.
The method of claim 11, wherein the bracket 110,
Interposed on the protruding surface of the support part 150 and connected to the flat plate part 111 where the bracket coupling hole 115 is formed and the flat plate part 111 and bent in a form corresponding to the outer surface of the flow path 515, A flow path fixing device comprising a bent portion (112) for holding and supporting the flow path.
The method of claim 1, wherein the flow path (515),
Flow path fixing device, characterized in that the heat exchange medium flow path for introducing or discharging the heat exchange medium to the heat exchanger (510) in which the heat exchange medium is distributed.
The method of claim 13, wherein the flow path fixing device 100,
The heat exchanger 510, a fan shroud 520 that is stacked and disposed with the heat exchanger 510, and a frame portion 550 that supports the heat exchanger 510 and the fan shroud 520 are combined and supported. The cooling module 500 is formed,
The support unit 150, the channel fixing device, characterized in that protrudingly formed in the region corresponding to the position where the passage 515 passes on the frame 550.
The method of claim 14, wherein the frame portion 550,
A flow path fixing device characterized in that it is a radiator tank portion.

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