WO2014027712A1 - Mini crane - Google Patents

Abstract

According to the present invention, a mini crane is capable of moving a weight in the up and down direction or right and left directions after being fixed on the inner wall of a building or on the ground and the weight is hung on the mini crane such that the weight can be easily moved to upper levels of a multiplex housing to which the weight is difficult to move. Further, the load of the weight can be supported using a jack (50), and first and second supports can be folded so as to decrease the volume when the mini crane is not in use.

Description

Mini Crane

The present invention relates to a minicrane, and more particularly, to a minicrane that can be fixed to the inner wall of the building to move a heavy load.

In general, cranes are also called cranes. The crane was the first of its kind, and was used to carry heavy loads when the pyramids were built in ancient Egypt some 5,000 years ago. At first, manpower or axial force was used, but later hydropower was used. From the mid-19th century, steam power was used along with the development of steam engines, resulting in mobile cranes. Since the end of the nineteenth century, electric power began to be used, and heavy-duty cranes developed rapidly to become the modern cranes of today.

Ceiling cranes are the most commonly used cranes and are so named because they are installed in the ceiling of factories and warehouses. Rails are laid along the walls facing each other and span a beam running at right angles to the rails. A trolley with hoisting and traversing devices is attached to this beam to lower the hooks from the trolley to lift the heavy goods.

With proper control of the beam travel and horizontal movement on the beam, cargo can be transported anywhere in the building. The small ones drive with manual chains on the ground. Usually a person rides in a cab suspended from a beam and drives there looking down at the cargo.

The most frequently used beams have a length of 6 to 26 m and a hoisting load of about 3 to 200 tons. Instead of the usual trolleys, hoists are called hoisted overhead cranes. Span is suitable for small-scale transportation with 6-10m and load 1-5t.

There is also a grab bucket, and there is also a grab bucket-mounted overhead crane dedicated to bulk materials. The load is about 1 to 8 tons. Slewing jib-mounted overhead cranes with swing jibs under the trolley can extend the unloading range beyond the length of the travel rail. The turning radius is 5 to 6.3m and the load is about 8t.

In addition, a dedicated overhead crane suitable for various operations is used in a steel mill. Either one must be able to withstand high temperatures and have high performance for heavy work. Important things include the raw material crane, the crane, the caster crane, the ingot crane, the soaking pit crane and the forging crane.

The unloader is a machine that unloads bulk cargo such as ore and coal. The unloader is loaded with a grab bucket and sent to the rear by a belt conveyor in the machine. Jib cranes, bridge cranes and combinations of these are available in a wide variety of types and types. In addition, it is the most economical gin pole for unloading the quay. poles, floating boxes equipped with jib cranes on low odd box vessels.

However, the conventional crane has a problem that the manufacturing cost is expensive because it generates power by using a prime mover. Particularly, in a multi-family building in which an elevator is not installed in a residential building, there is a problem in that a ladder truck must be used to transfer the goods upward.

An object of the present invention is to provide a mini crane that can be fixed to the inner wall of the building to move a heavy load.

The present invention is a column module (10); A horizontal module 20 coupled to the column module 10 and rotating; A support module 30 installed between the column module 10 and the horizontal module 20 to support the horizontal module 20 and guide the horizontal module 20 to be folded; It includes a cable module 40 for lifting the object by adjusting the length of the hook 42 installed in the horizontal module 20, the column module 10 is a base column 12 fixed to the ground and the base It provides a mini-crane comprising a rotating column 14 connected to the column 12 and rotated, and a relative rotating device 60 for relatively rotating the base column 12 and the rotating column 14.

The relative rotating device 60 is a worm shaft 62 is supported on the base column 12 and fixed to the rotating column 14; An operation gear 64 engaged with the worm shaft 62 to rotate the worm shaft 62; It may include a lever 66 for providing an actuation force to the actuating gear 64.

The support module 30 is a jack (jack, 50) fixed to the rotary column 14; A first supporter 32 hinged to the column bracket 15 to be rotated; It may include a second supporter 34 hinged to the first supporter 32 and the horizontal bracket 25, respectively.

The jack 50 is a jack base 52 is fixed to the rotating column 14; First and second support bars (53) (54) rotatably connected to the jack base (52); A first pin (55) connecting the jack base (52) so that the first and second support bars (53, 54) are rotated; Third and fourth support bars 56 and 57 connected to hinges 59a and 59b, respectively, to the first and second support bars 53 and 54; A second pin 58 connecting the third and fourth support bars 56 and 57 to rotate; Each hinge 59a is screwed so as to pass through each of the hinges 59a and 59b connecting the first and third support bars 53 and 56 and the second and fourth support bars 54 and 57. 59b) may include a screw adjustment bar (51) for separating or reducing the distance.

The cable module 40 has a hook 42 installed in the horizontal module 20; A winch 44 fixed to the column module 10; A winch cable 45 connecting the winch 44 and the hook 42; It may include a pulley 46 disposed inside the column module 10 and the horizontal module 20 to support the cable.

Another aspect of the invention the column module 10; A horizontal module 20 coupled to the column module 10 and including a hook 80 that is rotated and moves with a fixed weight; A support module 30 installed between the column module 10 and the horizontal module 20 to support the horizontal module 20 and guide the horizontal module 20 to be folded; A cable module 40 connected to the horizontal module 20 through the hook 80 and the winch cable 45 and adjusting the position of the hook 80 by winding or unwinding the winch cable 45; The brake module 70 is installed on the column module 10 and connected to the hook 80 through the control cable 71 and adjusts the position of the hook 80 by winding or unwinding the control cable 71. It includes, The cable module 40 is the hook 80 is installed and moved in the horizontal module 20; A winch 44 fixed to the column module 10; A winch cable 45 connecting the winch 44 and the hook 80; A pulley 46 disposed in the column module 10 and the horizontal module 20 to support the winch cable 45, wherein the brake module 70 is fixed to the column module 10. Box 72; A brake body 74 rotated about a body shaft 73 installed in the brake box 72; A brake 78 selectively interfering with the brake body 74 to intervene rotation of the brake body 74; A brake rotation lever (79) for rotating the brake body (74); It provides a mini-crane comprising a brake control lever for engaging or releasing the brake 78 and the brake body (74).

Minicracks according to the present invention can be fixed to the inner wall or ground of the building and can be moved up and down or left and right by hanging the heavy weight, through which there is an effect of easily moving the heavy weight on the high floor of the multi-family house difficult to move the heavy weight.

In addition, the minicrane according to the present invention can not only support the load of the heavy material using the jack, but also fold the first and second supporters, thereby minimizing the volume when not in use.

1 is a front view of a mini crane according to an embodiment of the present invention.

Figure 2 is a front view showing the folded state of Figure 1

3 is a plan view of FIG.

4 is an exemplary view showing the cable structure of FIG.

5 is a cross-sectional view showing a rotating structure of FIG.

6 is a front view showing the jack of FIG.

7 is a front view showing a mini crane according to another embodiment of the present invention.

8 is a schematic front view showing a mini crane according to another embodiment of the present invention.

9 is a partial cross-sectional view of the brake module of FIG. 8;

10 is a front sectional view of the hook shown in FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

However, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Even if the terms are the same, if the displayed portions are different, it is to be noted that the reference numerals do not match.

The terms to be described below are terms set in consideration of functions in the present invention, and may be changed according to a user's intention or custom such as an experimenter and a measurer, and the definitions should be made based on the contents throughout the present specification.

In this specification, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. The term and / or includes a combination of a plurality of related items or any item of a plurality of related items.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. A singular expression includes a plural expression unless the context clearly indicates otherwise.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

1 is a front view of a mini crane according to an embodiment of the present invention, FIG. 2 is a front view showing the folded state of FIG. 1, FIG. 3 is a plan view of FIG. 1, and FIG. 4 is a cable structure of FIG. 1. 5 is a cross-sectional view showing the rotating structure of Figure 1, Figure 6 is a front view showing the jack of FIG.

As shown, the minicrane according to the present embodiment is a column module 10, the horizontal module 20 is rotated by being coupled to the column module 10, the column module 10 and the horizontal module 20 Installed between the support module 30 to guide the horizontal module 20 and guides the horizontal module 20 folded, and by adjusting the length of the hook 42 provided in the horizontal module 20 to adjust the object It includes a cable module 40 for lifting.

The column module 10 includes a base column 12 fixed to the ground, a rotation column 14 connected to the base column 12 to rotate, and the base column 12 and the rotation column 14. A relative rotation device 60 for relatively rotating.

The base column 12 is manufactured by filling the concrete mortar after inserting the deformed steel reinforcement therein.

The rotating column 14 may be rotated relative to the base column 12 in the horizontal direction.

The upper end 16 of the rotating column 14 is hinged to the horizontal module 20, in this embodiment is formed in a predetermined length bent form.

The relative rotating device 60 is an operating gear for supporting the base column 12 and the worm shaft 62 fixed to the rotating column 14 and the worm shaft 62 to rotate the worm shaft 62. 64 and a lever 66 for providing an actuation force to the actuating gear 64.

The worm shaft 62 is a worm gear shape, the teeth are formed on the outer circumferential surface, the lower end generates a slip with the base column 12 when rotated. Here, the upper end is fixed to the rotating column 14, and when the worm shaft 62 is rotated, the worm shaft 62 is rotated together with the rotating column 14.

The operating gear 64 is a pinion shape that is meshed with the teeth of the worm gear. In this embodiment, only one pinion is installed, but a plurality of pinions are coupled in consideration of the rotation ratio to adjust the rotation angle per rotation of the lever 66. It may be.

The lever 66 is manually operated in this embodiment and causes the actuating gear 64 to rotate. Here, the lever 66 may be configured to rotate automatically by connecting the power unit unlike the present embodiment.

Thus, when the lever 66 is rotated, the worm shaft 62 engaged with the operating gear 64 is rotated so that a predetermined angle of the rotation column 14 fixed to the worm shaft 62 may be rotated.

On the other hand, bearings may be installed in each rotating part of the relative rotating device 60 to reduce friction.

The horizontal module 20 includes a first horizontal portion 22 hinged to the upper end 16 and a second horizontal portion 24 rotated relative to the first horizontal portion 22.

Here, the upper end 16 is formed with a rounded portion 16a which avoids interference with the first horizontal portion 22 when the first horizontal portion 22 is rotated downward, and the first horizontal portion ( A locking portion 16b is formed to prevent the 22 from being rotated upward in the horizontal state.

The first horizontal portion 22 is a round portion 22a for avoiding interference with the second horizontal portion 24 so as to be further rotated upward in a horizontal state, and the second horizontal portion 24 is in a horizontal state. The locking portion 22b is formed to prevent the rotation from below.

In the present embodiment, the first horizontal portion 22 is formed with a horizontal bracket 25 for hinge coupling with the support module 30. In addition, a column bracket 15 for hinge coupling with the support module 30 is formed in the rotary column 14.

The support module 30 includes a jack 50 fixed to the rotation column 14, a first supporter 32 hingedly connected to the column bracket 15, and the first supporter 32. And a second supporter 34 hinged to the horizontal bracket 25, respectively.

The jack 50 has a jack base 52 fixed to the rotating column 14, first and second support bars 53 and 54 rotatably connected to the jack base 52, and the first base. First and second pins 55 and 55 are connected to the jack base 52 so that the first and second support bars 53 and 54 rotate, and the hinges 59a to the first and second support bars 53 and 54, respectively. (59b) third and fourth support bars 56 and 57 connected to each other, second pins 58 to connect the third and fourth support bars 56 and 57 to rotate, and the first and third The distance between the hinges 59a and 59b is screwed through the hinges 59a and 59b connecting the support bars 53 and 56 and the second and fourth support bars 54 and 57. It includes a screw adjusting bar 51 to space or shrink.

The first, second, third, and fourth support bars 53, 54, 56, 57 are coupled in a rhombus shape so that each connection part can be rotated.

The first and second support bars 53 and 54 may be coupled to the jack base 52 by the first pin 55 and rotate about the first pin 55.

Here, the distance between each of the hinges (59a, 59b) is narrowed or spaced apart by the rotation of the screw adjustment bar 51, the height of the first and second pins (55, 58) through the link movement is Adjusted.

In the present embodiment, the jack 50 is installed between the first supporter 32 and the rotation column 14, the jack 50 is the first support according to the rotation angle of the first supporter 14 The rotational movement of the first supporter 32 is interpolated while being rotated about the pin 55.

Thus, the first supporter 32 may be rotated by the jack 50, and the load added to the first and second supporters 32 and 34 is supported by the jack 50.

In particular, the jack 50 is rotated when the horizontal module 20 is folded may be accommodated into the rotating column (14).

In the present embodiment, a mechanical jack operated by screwing is used, but unlike the present embodiment, a hydraulic cylinder operated by hydraulic pressure may be used.

The first supporter 32 is hinged to the column bracket 15 through a first supporter hinge 32a, and the second supporter 34 is connected to the horizontal bracket 25 through a second supporter hinge 34a. ) Is hinged.

The first and second supporters 32 and 34 may be connected to each other through the hinge 36 to be rotated relative to each other.

Here, when the horizontal module 20 is folded, the horizontal supporter 20 can be easily folded by removing the second support hinge 34a from the horizontal bracket 25.

The cable module 40 includes a hook 42 installed in the second horizontal portion 24, a winch 44 fixed to the column module 10, the winch 44 and the hook 42. It includes a winch cable 45 for connecting the pulley 46 is disposed in the column module 10 and the horizontal module 20 to support the cable.

The winch 44 is a machine for winding a cable around a cylindrical drum and using a pulley to lift or pull a heavy object to a high place, which is a general apparatus to those skilled in the art, and thus a detailed description thereof will be omitted.

In this case, the height of the hook 42 is changed by the operation of the winch 44 to lift or lower the weight.

The pulley 46 is installed in the column module 10 and the horizontal module 20 in the present embodiment, the winch cable 45 is arranged to be caught in the pulley 46 in a zigzag form the winch cable Distribute some of the load on (45).

Hereinafter, the operation of the mini crane according to the present invention will be described in more detail with reference to the accompanying drawings.

First, the winch 44 is operated to hook a heavy object to the hook 42, and the hook 42 is moved downward while the winch cable 45 is released by the operated winch.

Thereafter, by operating the winch 44, the winch cable 45 may be wound to move the weight upwards.

In addition, by rotating the lever 66 of the relative rotating device 60 in the forward or reverse direction, it is possible to rotate the rotary column 14 in the forward or reverse direction, through which the weight can be rotated in a predetermined direction.

On the other hand, when the mini crane is not used, the first and second supporters 32 and 34 may be folded by rotating the screw adjusting bar 51 of the jack 50.

7 is a front view showing a mini crane according to another embodiment of the present invention.

As shown, the minicrane according to the present embodiment is configured such that the horizontal bracket 25 installed in the horizontal module 20 can be moved along the rail 29 formed in the first horizontal portion 22.

The horizontal bracket 25 is provided with a moving wheel 27 is moved across the rail 29, the operation of the jack 50 in accordance with the relative angle of the first and second supporters 32, 34 The horizontal bracket 25 may move along the rail 29.

Thus, when the mini crane according to the present embodiment is folded, the horizontal module 20 can be folded using only the jack 50 even when the second support hinge hinge 34a of the horizontal bracket 25 is not released.

Hereinafter, the rest of the configuration is the same as the above embodiment and a detailed description thereof will be omitted.

FIG. 8 is a schematic front view of a minicrane according to another embodiment of the present invention, FIG. 9 is a partial cross-sectional view of the brake module of FIG. 8, and FIG. 10 is a front sectional view of the hook shown in FIG. 8.

As shown in the minicrane according to the present embodiment, the hook 80 may be moved along the horizontal module 20, and the horizontal movement or the vertical movement of the hook 80 may be selected through the brake module 70.

The horizontal module 20 has a hook rail 82 formed therein so that the hook 80 can be moved.

The hook 80 includes a hook roller 84 which is moved along the hook rail 82, and a hook portion 86 that is coupled to the hook roller 84 and the weight is fixed.

The hook rollers 84 are disposed in plural in this embodiment, and are moved along the respective hook rails 82.

The hook portion 86 is fixed to the hook roller 84, and is connected to the brake module 70 through a control cable 71.

The brake module 70 selectively interferes with the brake box 72 fixed to the column module 10, the brake body 74 installed on the brake box 72, and the brake body 74. The brake 78 for intermittent rotation of the brake body 74, the brake rotation lever 79 for rotating the brake body 74, and the brake 78 and the brake body 74 are coupled or released. A brake control lever (not shown) is included.

The brake body 74 includes a winding unit 75 to which the control cable 71 is wound, and a brake unit 76 coupled to the brake 78.

The brake 78 is selectively coupled to the brake unit 76 by the brake lever. In the present embodiment, the brake unit 78 maintains the state of being engaged with the brake unit 76 and operates the brake lever. Uncoupled with 76.

When the brake rotation lever 79 is rotated, the brake body 74 is rotated about the body shaft 73 to wind or loosen the control cable 71 to adjust the position of the hook 80. Can be.

The brake control lever is a mechanism for contacting or non-contacting with the brake unit 76 through a mechanical operating force, and thus a detailed description thereof will be omitted.

Hereinafter, an operation process of the brake module 80 interlocked with the cable module 40 will be described with reference to the drawings.

First, when the brake 78 is coupled to the brake body 74, when the cable module 40 is operated to wind or unwind the winch cable 45, the hook 80 and the brake module ( Since the length of the control cable 71 of the 70 is constant, the hook 80 is moved in the vertical direction.

Next, when the brake 78 is released, the hook 80 may be moved in the vertical direction as well as the left and right directions by the operation of the winch 44 or the brake rotation lever 79.

For example, when the control cable 71 is wound through the brake rotation lever 79 as long as the winch cable 45 is released by the winch 44, the hook 80 is moved to the left in FIG. 8. Is moved.

On the contrary, when the winch cable 45 is wound as long as the control cable 71 is released, the control cable 71 is moved in the right direction in FIG. 8.

In addition, according to the length of the winch cable 45 and the control cable 71 is wound or unrolled, the hook 80 may be moved in a diagonal direction, when interlocked with the relative rotating device 60, The hook 80 can be quickly moved to any point.

Hereinafter, the rest of the configuration is the same as the above embodiment and a detailed description thereof will be omitted.

Although described with reference to the above embodiments, those skilled in the art will understand that various modifications and changes can be made without departing from the spirit and scope of the invention as set forth in the claims below. Could be.

Claims (6)

1. Column module 10;

   A horizontal module 20 coupled to the column module 10 and rotating;

   A support module 30 installed between the column module 10 and the horizontal module 20 to support the horizontal module 20 and guide the horizontal module 20 to be folded;

   It includes a cable module 40 for lifting the object by adjusting the length of the hook 42 installed in the horizontal module 20,

   The column module 10 includes a base column 12 fixed to the ground, a rotation column 14 connected to the base column 12 to rotate, and the base column 12 and the rotation column 14. Mini crane comprising a relative rotation device 60 for relative rotation.
2. The method according to claim 1,

   The relative rotating device 60

   A worm shaft 62 supported by the base column 12 and fixed to the rotary column 14;

   An operation gear 64 engaged with the worm shaft 62 to rotate the worm shaft 62;

   And a lever (66) for providing an actuation force to the actuating gear (64).
3. The method according to claim 1,

   The support module 30 is

   A jack (50) fixed to the rotary column (14);

   A first supporter 32 hinged to the column bracket 15 to be rotated;

   Mini-crane comprising a second supporter (34) hinged to the first supporter (32) and the horizontal bracket (25), respectively.
4. The method according to claim 3,

   The jack 50 is

   A jack base 52 fixed to the rotating column 14;

   First and second support bars (53) (54) rotatably connected to the jack base (52);

   A first pin (55) connecting the jack base (52) so that the first and second support bars (53, 54) are rotated;

   Third and fourth support bars 56 and 57 connected to hinges 59a and 59b, respectively, to the first and second support bars 53 and 54;

   A second pin 58 connecting the third and fourth support bars 56 and 57 to rotate;

   Each hinge 59a is screwed to penetrate the hinges 59a and 59b connecting the first and third support bars 53 and 56 and the second and fourth support bars 54 and 57, respectively. Mini-crane comprising a screw adjustment bar (51) for separating or reducing the distance of 59b).
5. The method according to claim 1,

   The cable module 40 is

   A hook 42 installed in the horizontal module 20;

   A winch 44 fixed to the column module 10;

   A winch cable 45 connecting the winch 44 and the hook 42;

   Mini-crane comprising a pulley (46) disposed inside the column module (10) and the horizontal module (20) to support the cable.
6. Column module 10; A horizontal module 20 that is coupled to the column module 10 and includes a hook 80 that is rotated and moves with a fixed weight; A support module 30 installed between the column module 10 and the horizontal module 20 to support the horizontal module 20 and guide the horizontal module 20 to be folded; A cable module 40 connected to the horizontal module 20 through the hook 80 and the winch cable 45 and adjusting the position of the hook 80 by winding or unwinding the winch cable 45; The brake module 70 is installed on the column module 10 and connected to the hook 80 through the control cable 71 and adjusts the position of the hook 80 by winding or unwinding the control cable 71. Including,

   The cable module 40 is

   The hook 80 is installed and moved to the horizontal module 20; A winch 44 fixed to the column module 10; A winch cable 45 connecting the winch 44 and the hook 80; A pulley 46 disposed in the column module 10 and the horizontal module 20 to support the winch cable 45,

   The brake module 70

   A break box 72 fixed to the column module 10; A brake body 74 rotated about a body shaft 73 installed in the brake box 72; A brake 78 selectively interfering with the brake body 74 to intervene rotation of the brake body 74; A brake rotation lever (79) for rotating the brake body (74); Mini-crane comprising a brake control lever for engaging or releasing the brake (78) and the brake body (74).

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