KR200374402Y1 - structure of heat-sink in a crane - Google Patents

Abstract

The present invention relates to a heat sink structure in which the heat sink structure installed in the crane sheave body is improved so as to minimize impact upon contact with the ground, and the structure is connected to an upper heat sink plate extending downward to one side of the crane sheave body. And a lower heat sink plate rotatably connected to the lower portion of the upper heat sink plate by a connecting ring.

The connection portion of the upper and lower heat sink plate is formed with a connection hole is fitted with a coupling ring in the corresponding position, respectively.

According to the present invention, by dividing the structure of the heat sink up and down to enable mutual rotation, the crane sheave body has a useful effect of reducing the impact transmitted to the heat sink when it touches the ground to improve the durability of the product.

Description

Heat sink structure of crane {structure of heat-sink in a crane}

The present invention relates to a heat sink structure of a crane, and more particularly, to a heat sink structure of a crane whose structure is improved to prevent deformation and damage even when touching the ground by improving the structure of the heat sink manufactured perpendicularly to the outside of the crane sheave body. .

In general, a crane is a device for carrying a heavy object in the vertical direction or horizontal direction, and is classified into top crane, ceiling crane, jib crane, and the like according to its function and shape.

Here, the ceiling crane will be described as an example, but the conventional ceiling crane is installed in close proximity to the ceiling as shown in FIG. 1, and the crane body 12 installed to be movable left, right, and forward and backward, and the crane. Crane sheave consisting of loop sheave 14 and hook sheave 15 which are interlocked and rotated when the motor (not shown) installed in main body 12, and wire rope wound by loop sheave 14 and hook sheave 15 And a hook 16 or the like, which is pivotally attached to the hook sheave 15 so as to interlock with the lifting and lowering of the wire rope 17.

In the crane having such a configuration, the wire 16 is moved up and down by the lifting and unwinding of the wire rope 17 while the wire rope 17 is wound or unwound by the loop sheave 14 by the rotation of the motor. After the structure is hooked to the hook 16, it is configured to move up and down and move left and right and move to other facilities.

In addition, the power of the motor is transmitted to the transverse wheel through the shaft to move the transverse vehicle, wire rope 17 is connected to the loop sheave 14 and the hook sheave 15, respectively, the power of the motor loop sheave As the 14 is received and rotated, the wire rope 17 is wound around the loop sheave 14.

The structure for fixing the existing hook sheave (hereinafter referred to as crane sibra) is as shown in Figure 2, the crane sheave 15 to the crane sheave body 20 is horizontally coupled to the pin by the hook pin 22 And, the crane hook 16 is rotatably coupled to the lower side of the crane sheave body 20, the heat sink 30 for blocking the heat of the ladle (not shown) vertically to one side of the crane sheave body 20 It has a structure to be installed.

By the way, the existing heat sink installation structure has a structure in which the upper end of the heat sink 30 is integrally connected by welding or a separate connection member (not shown) to the crane sheave body 20, for work such as grease injection When the crane sieve body is lowered to the ground, the lower part of the heat sink is in contact with the ground, and there is a problem in that it is damaged and deformed by the impact, thereby preventing the function of the heat sink.

The present invention has been proposed to solve the above problems in view of the above problems, and its purpose is to improve the structure of the heat sink installed in the crane sheave body, so that the structure is improved to prevent deformation or breakage by reducing the impact even if the ground contact To a heat sink structure of a mounted crane.

1 is a front view showing the structure of a typical overhead crane.

Figure 2 is a perspective view of the main part showing a heat sink installation structure of a conventional crane.

Figure 3 is a perspective view of the main part showing an embodiment of the heat sink structure of the crane according to the present invention.

Figure 4 is a state of use showing the state of use of one embodiment of the present invention.

Figure 5 is a perspective view of the main part showing another embodiment of the present invention.

6 is a state diagram used in another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

20: crane sheave body 30: heat sink

31: connecting hole 32: upper heat sink plate

34: lower heat sink plate 42: connection ring

The present invention for achieving the above object in the heat sink structure connected to the vertical side down one side of the crane sheave body,

The heat sink is an upper heat sink plate connected to the crane sheave body,

And a lower heat sink plate rotatably connected to the lower portion of the upper heat sink plate by a connecting means.

In another feature of the present invention, the connecting means is formed with a plurality of connection holes respectively corresponding to the lower side of the upper heat sink plate and the lower side of the heat sink plate,

Connection rings are fitted to each of the connection holes for rotation of the lower heat sink plate.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the same components as the components of the conventional crane described above will be denoted by the same reference numerals and redundant descriptions will be omitted.

One embodiment of the heat sink structure of the crane according to the present invention, when described with reference to Figures 3 and 4, the structure is the upper heat sink plate 32 is connected to extend to one side of the crane sheave body 20 and the lower side The lower heat sink plate 34 is rotatably connected to the lower portion of the upper heat sink plate 32 by a connecting ring 42.

In more detail, the lower heat sink plate 34 has a structure that is symmetrical with each other about the upper heat sink plate 32 and the link ring 42, and the upper heat sink plate ( The connection hole 31 corresponding to each of the lower part of the lower part 32 and the upper side of the lower heat sink plate 34 is formed.

The connecting ring 42 is coupled to be fitted into the connection hole 31 of the upper and lower heat sink plates 32 and 34, respectively, the structural form is wound in a circular ring a plurality of times so that one side is opened, It is possible to adopt a hook type that can be simply hooked up and down.

In addition, the upper heat sink plate 32 has a structure rotatably connected to one side flange portion of the crane sheave body 20 via the hook 25.

In addition, the lower heat sink plate 34 is preferably formed with an extension portion 35 extending horizontally to the crane sheave side (hereinafter referred to as an inner side).

This is to prevent heat transmitted from the ladle (not shown) from being transferred inward through the lower side of the lower heat sink plate 34.

Referring to the operation of the present invention having such a structure is as follows.

In the heat sink structure of the present invention, when lowering the wire rope 17 of the crane for work such as grease injection into the crane sheave body 20, even if the crane sheave body 20 is in contact with the ground, the lower heat sink plate 34 is The lower part of the upper heat sink plate 32, that is, the connection ring 42 is rotated to either of the inside and the outside.

Therefore, the lower surface of the lower heat sink plate 34 is not vertically positioned with respect to the ground, but is bent to one of the inner and outer sides, and thus shock absorbing against the ground is possible.

In addition, if the wire rope 17 is lifted again to return the crane sheave body 20 back to its original position after the work on the ground is completed, the lower heat sink plate 34 returns to its original position with respect to the connecting ring 42. The return operation is performed as described above and positioned vertically below the upper heat sink plate 32.

On the other hand, Figure 5 and Figure 6 shows another embodiment of the present invention, the structure is divided into the upper heat sink plate 32 and the lower heat sink plate 34 is the same as the embodiment described above, but the connecting means It is a structure that is hinge-bonded, not the ring coupling, is formed to protrude to the lower surface of the upper heat sink plate 32 and the fixing bracket 32a formed to open the hinge coupling hole (32b) on both sides, and the fixing bracket ( The support bracket 34a is formed to protrude on the upper surface of the lower heat sink plate 34 so as to receive the support 32a, and the hinge coupling holes 34b are formed on both sides thereof, and the support bracket 34a and the fixing bracket 32a are provided. The hinge coupling holes 32b and 34b are composed of hinge pins 33 that are pin-coupled to penetrate through each other.

That is, mutually uneven brackets are formed at the coupling portions of the upper heat sink plate 32 and the lower heat sink plate 34, and the brackets are pin-coupled to be rotatable by the hinge pins 33.

In addition, the structure of the hinge pin 33 has a screw thread formed on the outer peripheral surface of the end of the pin, a fastening nut fastened to the screw thread may be provided as a pair.

Here, the support bracket 34a is represented as a structure for receiving the fixed bracket 32a, but on the contrary, the fixed bracket 32a may be configured to accommodate the support bracket 34a.

The present invention described as described above relates to a heat sink structure in which the heat sink structure installed in the crane sheave body is improved to minimize the impact when contacted with the ground. By being divided and rotatable to each other, the crane sheave body has a useful effect of reducing the impact transmitted to the heat sink when it reaches the ground to improve the durability of the product.

Claims (2)

In the heat sink structure connected vertically downward to one side of the crane sheave body 20, The heat sink 30 is the upper heat sink plate 32 is connected to the crane sheave body 20, Heat sink structure of the crane, characterized in that consisting of a lower heat sink plate 34 rotatably connected by a connecting means to the lower portion of the upper heat sink plate (32). According to claim 1, The connecting means is formed in the lower portion of the upper heat sink plate 32 and the plurality of connecting holes 31 respectively corresponding to the upper side of the lower heat sink plate 34, respectively, Heat sink structure of the crane, characterized in that the coupling ring 42 is fitted to each of the connection hole 31 for the rotation of the lower heat sink plate (34).