JP7342904B2 - Hanging equipment - Google Patents

Description

The present invention relates to a lifting device for lifting and transporting a non-magnetic object using a crane equipped with an electromagnetic lifting device.

Generally, when transporting a heavy non-magnetic object using cargo handling equipment such as a crane, the object is lifted using a lifting device such as a sling, wire, hacker, clamp, or vacuum lifter.
When hoisting an object (hanging load), lifting tools other than vacuum lifters require manual sling work such as binding and releasing the hanging load, and attaching and detaching the lifting tool. This sling work is not only laborious as it requires manual labor, but also requires sufficient measures to ensure safety because the distance between the suspended load and the worker is close. On the other hand, in the case of a vacuum lifter, it is necessary to create a vacuum state between the lifter and the suspended load, resulting in poor work efficiency.

On the other hand, as an electric tongs equipped with a lifting magnet (electromagnetic hanger) that eliminates the need for sling work and improves the problems of vacuum lifters, for example, those shown in Patent Document 1 are known.
The electric tongs with a lifting magnet disclosed in Patent Document 1 includes an electric tongs which is provided with a claw for placing a steel plate on the lower end of each arm on a suspension stand suspended from a crane wire, and a lifting magnet which is hung via an upper hook. It is also equipped with an electric churn block that moves up and down.

Utility Model Publication No. 6-10283

However, the conventional electric tongs with a lifting magnet shown in Patent Document 1 has the following problems.
That is, in the case of the electric tongs with a lifting magnet shown in Patent Document 1, it is not possible to lift and transport a non-magnetic object. Further, since the lifting magnet has a flat shape, the suspended load that can be attracted by the lifting magnet is limited to a plate shape, and it is not possible to transport suspended loads of various shapes. Further, there was a problem that the hanging tool itself had a large-scale structure and the manufacturing cost was high.

Therefore, the present invention was made to solve this conventional problem, and its purpose is to provide a crane equipped with an electromagnetic hoist that eliminates the need for manual sling work and is constructed at low cost. An object of the present invention is to provide a lifting tool that can be used to lift and transport non-magnetic objects of various shapes.

In order to solve the above problems, a lifting device according to one aspect of the present invention is a lifting device for lifting and transporting a non-magnetic object using a crane equipped with an electromagnetic lifting device, a fixed top plate, a hanging load holding part that is fixed to a fixed part provided on the fixed top plate and holds the object, and can be changed from a state overlapping with the fixed top plate to a state separated from the fixed top plate. The fixing part and/or a rotating top plate made of a magnetic material rotatably supported with respect to the fixed top plate, the rotating top plate being overlapped with the fixed top plate. The gist is that when the electromagnetic hanger stops attracting the electromagnetic hanger, the electromagnetic hanger changes to a state where it is isolated from the fixed top plate.

According to the hanging tool of the present invention, non-magnetic objects of various shapes are lifted and transported using a crane equipped with an electromagnetic lifting tool, which eliminates the need for manual sling work and is constructed at low cost. can do.

FIG. 1 is a perspective view of a hanging tool according to an embodiment of the present invention. FIG. 2 is a perspective view of the hanging tool shown in FIG. 1 in a state where the rotary top plate is disassembled from the fixed top plate and the hanging load holding part. FIG. 2 is an explanatory diagram for lifting and transporting an object using the hanging tool shown in FIG. 1, and is a perspective view of a state in which one end of the wire is connected to the hanging ring of the hanging tool. This is an explanatory diagram for hoisting and transporting an object using the lifting device shown in FIG. It is a perspective view of a state where the end is hung over a hook of a crane. This is an explanatory diagram for hoisting and transporting an object using the hanging tool shown in FIG. 1. From the state shown in FIG. FIG. This is an explanatory diagram for lifting and transporting an object using the lifting tool shown in Figure 1.The object is transported from the state shown in Figure 5 to the target location, and the electromagnetic lifting tool stops adsorbing the rotating top plate. It is a perspective view of a state. This is an explanatory diagram for hoisting and transporting an object using the hanging tool shown in FIG. 1, and a perspective view of a state in which the fixed top plate and the suspended load holding part rotate from the state shown in FIG. 6, and the object falls. be.

Embodiments of the present invention will be described below with reference to the drawings. The embodiments shown below illustrate devices and methods for embodying the technical idea of the present invention. It is not limited to the embodiments described below. Furthermore, the drawings are schematic. Therefore, it should be noted that the relationships, ratios, etc. between thickness and planar dimensions are different from those in reality, and the drawings also include portions where the relationships and ratios of dimensions are different.

FIG. 1 shows a hanging device according to an embodiment of the present invention. The lifting tool 1 shown in FIG. This is a lifting device for lifting and transporting (see).
The object T is an offcut of a hot-rolled austenitic stainless steel plate such as SUS304, which is made of a non-magnetic material. Here, "non-magnetic material" means a material that cannot be lifted and transported by magnetic force, and includes all of paramagnetic, diamagnetic, and antiferromagnetic materials, and also includes so-called weak magnetism. It is.

The hanging tool 1 shown in FIG. 1 includes a fixed top plate 10, a plurality of (two in this embodiment) hanging load holding parts 20, and a rotating top plate 30.
Here, the fixed top plate 10 is a rectangular magnetic metal member having a length l10, a width b10, and a plate thickness t10, as shown in FIG. "Magnetic material" means a material that can be lifted and transported by magnetic force, and refers to a ferromagnetic material. The fixed top plate 10 is made of, for example, a stainless steel plate other than an austenitic stainless steel plate or a carbon steel plate. In this embodiment, the length l10 and the width b10 of the fixed top plate 10 are set to about 530 mm and about 500 mm, respectively, taking into account the dimensions of the electromagnetic hanger (lifting magnet) 53 placed on the top surface. Further, the plate thickness t10 of the fixed top plate 10 is set to approximately 8 mm in this embodiment, taking into consideration the hanging load of the object T.

A pair of fixing parts 11 are provided at both widthwise ends of the lower surface of the fixed top plate 10. Each fixing part 11 includes a fixed top plate fixing part 11a extending linearly in the longitudinal direction of the fixed top plate 10, and a hanging load holding part fixing part 11b extending linearly downward from one end of the fixed top plate fixing part 11a. It is an L-shaped magnetic metal member. "Magnetic material" means a ferromagnetic material. Each fixing plate portion 11 is made of, for example, a stainless steel plate other than an austenitic stainless steel plate or a carbon steel plate. The fixed top plate 10 is joined and fixed onto the fixed top plate fixing portions 11a of the pair of fixing portions 11 by welding or the like.
Furthermore, a fixing hole 11c into which a pin portion of a connecting pin 40 (described later) is press-fitted is formed at the intersection of the fixed top plate fixing portion 11a of each fixing portion 11 and the suspended load holding portion fixing portion 11b. .

Moreover, each hanging load holding part 20 holds the target object T, and is fixed to the hanging load holding part fixing part 11b of each fixing part 11. As shown in FIG. 2, each hanging load holding part 20 is arranged in a straight line on the side opposite to the side where the fixed top plate 10 is arranged with respect to the hanging load holding part fixing part 11b of the fixed part 11, that is, on the lower side. A fixed plate part 20a fixed by welding or the like so as to extend; and a fork part 20b linearly extending from the lower end of the fixed plate part 20a so as to be perpendicular to the fixed plate part 20a and facing the fixed top plate 10. It is an L-shaped non-magnetic metal member. "Nonmagnetic material" includes all of paramagnetic, diamagnetic, and antiferromagnetic materials, and also includes so-called weak magnetism. The hanging load holding section 10 is made of a non-magnetic material, for example, a hot-rolled austenitic stainless steel plate such as SUS304.

When lifting and transporting the object T, the object T is held by the fork portion 20b, and specifically placed on the fork portion 20b, as shown in FIGS. 5 to 7. The width of the fixed plate part 20a of each suspended load holding part 20 is b20, the length of the fork part 20b is l20, the thickness of each of the fixed plate part 20a and the fork part 20b is t20, the distance between the two suspended load holding parts 20 The interval is D20, and the height from the bottom surface of each suspended load holding part 10 to the top surface of the fixed top plate 10 is h20. The width b20 of the fixed plate portion 20a of each suspended load holding portion 20 is set to approximately 100 mm in this embodiment, considering the durability of each suspended load holding portion 20. Furthermore, the plate thickness t20 of each of the fixed plate part 20a and the fork part 20b is also set to about 22 mm in this embodiment, considering the durability of each suspended load holding part 20. Further, the length l20 of the fork portion 20b is set to approximately 500 mm in this embodiment, taking into consideration the dimensions, number, and weight of the objects T to be lifted and conveyed. Moreover, the distance D20 between the two hanging load holding parts 20 is also set to about 450 mm in this embodiment, taking into account the dimensions, number, and weight of the objects T to be lifted and conveyed. In addition, the height h20 from the bottom surface of each suspended load holding section 10 to the top surface of the fixed top plate 10 is also set to approximately 570 mm in this embodiment, taking into account the dimensions, number, and weight of the objects T to be lifted and conveyed. Ru.

Further, as shown in FIGS. 3 to 7, the rotary top plate 30 has fixed parts provided on the fixed top plate 10 so that the rotating top plate 30 can be changed from an overlapping state to a separated state from the fixed top plate 10. 11 so as to be rotatable.
As shown in FIG. 2, this rotary top plate 30 is a rectangular shape whose length and width are set to be approximately the same as the length l10 and width b10 of the fixed top plate 10, and whose plate thickness is t30. It is a magnetic metal member with a shape. "Magnetic material" means a ferromagnetic material. The rotating top plate 30 is made of, for example, a stainless steel plate other than an austenitic stainless steel plate or a carbon steel plate. Further, the plate thickness t30 of the rotary top plate 30 is set to approximately 8 mm in this embodiment, taking into consideration the hanging load of the object T.

A pair of mounting plate portions 31 (only one of which is shown in FIG. 2) is provided at both widthwise edges of the rotary top plate 30 at positions corresponding to the hanging load holding portion fixing portions 11b in the longitudinal direction. There is. Each mounting plate portion 31 is a rectangular portion formed by bending downward from a position corresponding to the hanging load holding portion fixing portion 11b in the longitudinal direction on both widthwise edges of the rotary top plate 30, and has a center portion which will be described later. An insertion hole 31a is formed into which the shaft portion of the connecting pin 40 is inserted.
Further, on the upper surface of the rotary top plate 30, as shown in FIGS. 2 to 4, a plurality of (four in this embodiment) hanging rings 32 are connected to an electromagnetic hanging tool (lifting magnet) 53 by a wire W. It is provided. The hanging rings 32 are provided at the four corners of the rotary top plate 10. Each hanging ring 32 is formed with a connecting hole 32a to which one end of the wire W is connected.

When the rotating top plate 30 is attached to each hanging load holding part fixing part 11b, as shown in FIGS. Each attachment plate part 31 is located outside each suspended load holding part fixing part 11b. When each attachment plate part 31 is located outside each hanging load holding part fixing part 11b, the insertion hole 31a of each attachment plate part 31 is aligned with the fixing hole 11c formed in each hanging load holding part fixing part 11b. Then, the shaft portion of the connecting pin 40 is inserted through the insertion hole 31a of each mounting plate portion 31 and press-fitted into the fixing hole 11c. As a result, the rotary top plate 30 is rotatably supported by the connecting pins 40 on the respective suspended load holding portion fixing portions 11b with the heads of the connecting pins 40 preventing the attachment plate portions 31 from coming off. The connecting pin 40 is made of a magnetic material, for example carbon steel.

In the hanging tool 1 configured in this way, the rotating top plate 30 is attracted to the electromagnetic hanging tool (lifting magnet) 53 while overlapping the fixed top plate 10, as shown in FIGS. 5 to 7. When the electromagnetic hanger 53 stops attracting, the state changes to a state where it is isolated from the fixed top plate 10.

Next, with reference to FIGS. 3 to 7, a method for lifting and transporting the object T using the hanging tool 1 shown in FIG. 1 will be described.
The lifting tool 1 is a lifting tool for lifting and transporting a non-magnetic object T using a crane (not shown) equipped with an electromagnetic lifting tool (lifting magnet) 53. As shown in FIG. 4, the crane has a flat electromagnetic hoist 53 supported by a support member 54 via a hoist ring 55 suspended from a hook 52 suspended from a crane wire 51. Then, the crane raises the electromagnetic lifting device (lifting magnet) 53 by hoisting the crane wire 51, and lowers the electromagnetic lifting device (lifting magnet) 53 by hoisting the crane wire 51 down.

First, when lifting and transporting the object T using the lifting tool 1, as shown in FIG. It is connected to the hanging ring 32.
Next, as shown in FIG. 4, the electromagnetic hanging tool 53 provided in the crane is placed in the center of the upper surface of the fixed top plate 30, and the other end of each wire W, one end of which is connected to the hanging ring 32, is connected to the hanging ring 55. Connect to. Thereby, the rotary top plate 30 and the electromagnetic hanger 53 are connected by the plurality of wires W.

Next, the electromagnetic hanger 53 is excited and the rotary top plate 30 is attracted by the electromagnetic hanger 53. At this time, since the rotary top plate 30 is a magnetic material, it is smoothly attracted to the electromagnetic hanger 53. Since the fixed top plate 10 is also made of magnetic material, the fixed top plate 10 is attracted to the rotating top plate 30. Further, since the fixed top plate 10 is attracted to the rotating top plate 30, the hanging load holding part 20 is fixed to the electromagnetic hanger 53 via the fixing part 11.
In this state, the hoist 1 is moved by the crane to a place where the object T is placed, for example, an offcut (object T) cut to the required size from a hot-rolled austenitic stainless steel plate such as SUS304. As shown in FIG. 5, the lifting tool 1 is raised and lowered to remove a plurality of objects T (only two are shown in FIG. 5) using the fork part 20b of the hanging load holding part 20. (place the object T on the fork part 20b).

Thereafter, the lifting tool 1 is moved by a crane to a target location, for example, above a disposal site for scraps, and as shown in FIG. 6, the excitation of the electromagnetic lifting tool 53 is stopped (released). As a result, the electromagnetic hanger 53 stops adsorbing the rotary top plate 30, and the state of adsorption of the fixed top plate 10 to the rotary top plate 30 is also stopped. As a result, the rotary top plate 30 tends to fall due to its own weight, and the fixed top plate 10 begins to rotate downward around the connecting pin 40 due to its own weight, as shown in FIG.

At this time, as shown in FIG. 6, since the rotating top plate 30 and the electromagnetic hanger 53 are connected by a plurality of wires W, the rotating top plate 3 is prevented from falling due to its own weight, and only the fixed top plate 10 is begins to rotate downward around the connecting pin 40 due to its own weight.
Then, as shown in FIG. 7, the fixed top plate 10 continues to rotate downward due to its own weight, and the fork portion 20b of the hanging load holding section 20 fixed to the fixed top plate 10 tilts downward. As a result, the object T held by the fork part 20b (placed on the fork part 20b) slides down on the fork part 20b, and the object T falls to a target location, for example, a place for discarding scraps. .

With the above operations, lifting and transporting of the object T using the lifting tool 1 shown in FIG. 1 is completed.
In addition, when lifting and transporting the object T using the lifting tool 1 shown in FIG. 1 is repeated, the fixed top plate 10 is returned from the state shown in FIG. If the hanging tool 53 is excited, the rotating top plate 30 is attracted by the electromagnetic hanging tool 53, the hanging tool 1 is moved to the location where the object T is placed by a crane, and the conditions shown in FIGS. 5 to 7 are repeated. good.
As described above, according to the hanging device 1 according to the present embodiment, the hanging device 1 that is fixed to the magnetic fixed top plate 10 and the magnetic fixing portion 11 provided on the fixed top plate 10 and that holds the object T. It includes a load holding part 20 and a rotary top plate 30 made of a magnetic material and rotatably supported with respect to the fixed part 11 so that the state can be changed from an overlapping state to a separated state with respect to the fixed top plate 10. There is. Then, the rotating top plate 30 is attracted to the electromagnetic hanger 53 while overlapping with the fixed top plate 10, and when the electromagnetic hanger 53 stops adhering, the rotating top plate 30 is changed to a state separated from the fixed top plate 10. be done.

Thereby, the non-magnetic object T can be efficiently lifted and transported using a crane equipped with the electromagnetic lifting tool 53 without requiring manual sling work. In addition, even if the electromagnetic hanger 53 is flat, the hanging device 1 holds the object T by the hanging load holding section 20, so that it is possible to lift and transport the object T in various shapes other than a plate shape. I can do it. In addition, the hanging tool 1 is composed of a fixed top plate 10 made of a magnetic material provided with a fixing part 11, a hanging load holding part 20, and a rotating top plate 30 made of a magnetic material, so that the structure is simple and inexpensive. Can be configured.
Moreover, since the suspended load holding part 20 is a non-magnetic material, the suspended load holding part 20 is not magnetized when the electromagnetic hanger 53 is excited and the rotary top plate 30 is attracted by the electromagnetic hanger 53. Therefore, when the suspended load holding section 20 holds the non-magnetic object T, the suspended load holding section 20 does not hold any magnetic material other than the object T, such as magnetic chips. , unnecessary retention of magnetic material can be avoided.

Further, the rotating top plate 30 is provided with a hanging ring 32 connected to an electromagnetic hanging tool 53 by a wire W. Therefore, even if the electromagnetic hanging device 53 stops adsorbing the rotating top plate 30 and the rotating top plate 30 tries to fall due to its own weight, the rotating top plate 30 It is possible to reliably prevent the product from falling due to its own weight.
Further, the hanging load holding section 20 holds an object T extending from the end of the fixed plate section 20a fixed to the fixed section 11 so as to be perpendicular to the fixed plate section 20a and facing the fixed top plate 10. Fork portion 20b is provided. Thereby, there are fewer restrictions on the shape of the objects T to be hung, and the orientation of the objects T to be held can be easily aligned, so that cargo collection can be performed easily.

Although the embodiments of the present invention have been described above, the present invention is not limited thereto, and various changes and improvements can be made.
For example, the shapes of the rotating top plate 30 and the fixed top plate 10 may be appropriately changed according to the shape of the electromagnetic hanger 53, and are not limited to the rectangular shape, and the dimensions and the like are not limited to the example described.
Further, the rotating top plate 30 does not necessarily need to be rotatably supported only with respect to the fixed part 11, but can be rotatably supported with respect to the fixed top plate 10 itself or both the fixed top plate 10 and the fixed part 11. may have been done.
Further, the hanging load holding section 20 does not necessarily need to be made of a non-magnetic material, and may be made of a magnetic material.
Moreover, the fixing part 11 does not necessarily need to be a magnetic material, and may be a non-magnetic material.

Further, the rotating top plate 10 does not necessarily need to be provided with the hanging ring 32 connected to the electromagnetic hanging tool 53 by the wire W. This is because by finely adjusting the magnetic force of the electromagnetic hanger 53, it is possible to prevent the rotary top plate 30 from falling due to its own weight.
In addition, if the hanging load holding part 20 holds the object T and is fixed to the fixing part 11, the hanging load holding part 20 includes a fixing plate part 20a fixed by welding or the like so as to extend linearly to the fixing part 11. , the fork portion 20b extends linearly from the lower end of the fixed plate portion 20a so as to be perpendicular to the fixed plate portion 20a and to face the fixed top plate 10. Further, the dimensions of the hanging load holding section 20 are not limited to the example described.
Moreover, although two hanging load holding parts 20 are installed in this embodiment, there is no restriction|limiting in number, and it may be one or two or more.

Further, a rotation regulating mechanism (not shown) may be provided to regulate the rotation angle of the fixed top plate 10 with respect to the rotary top plate 30, so as to regulate the inclination angle of the fork portion 20b of the suspended load holding portion 20. For example, a chain (not shown) or the like as a rotation regulating mechanism may be installed between the fixed top plate 10 and the rotating top plate 30. As a result, after stopping the excitation of the electromagnetic hanger 53, the fixed top plate 10 continues to rotate downward due to its own weight, and the fork portion 20b of the suspended load holding unit 20 fixed to the fixed top plate 10 moves downward. The angle of inclination is regulated when it is tilted towards. Therefore, the falling speed when the object T slides and falls on the fork portion 20b can be limited, and safety can be improved.

Further, a braking device (not shown) may be provided to limit the rotational speed of the fixed top plate 10. For example, a brake device (not shown) may be pressed against the outer peripheral surface of the connecting pin 40 that rotates together with the fixed top plate 10. As a result, after stopping the excitation of the electromagnetic hanger 53, the fixed top plate 10 continues to rotate downward due to its own weight, and the fork portion 20b of the suspended load holding unit 20 fixed to the fixed top plate 10 moves downward. When the fork portion 20b is tilted toward the vehicle, the rotational speed of the fork portion 20b can be limited, and safety can be improved.

(Example 1)
Offcuts with dimensions 10mm thick x 50mm wide x 1500mm long generated after cutting a steel plate with dimensions 10mm thick x 2000mm wide x 9000mm long from a hot-rolled SUS304 steel plate with dimensions 10mm thick x 2500mm wide x 10000mm long. are collected and lifted in units of 20 using a semi-gantry crane equipped with an electromagnetic lifting device 53 and the lifting device 1 shown in Figures 1 and 2, and transported from inside the cutting site to above the bag dedicated to offcuts outside the cutting site. did. The dimensions and material of the hanging tool 1 are as described in the explanation of FIGS. 1 and 2, and the rated load is 250 kg. After transporting the scraps to the air above the bag, the excitation of the electromagnetic hanger 53 is stopped (released), and unloading is completed.
At this time, the operator completed the series of work safely and in a short time without any manual slinging work on the hanging load and the hanging tool 1. Thereafter, the electromagnetic hanger 53 was energized again and the work was repeated to finish cleaning up the scraps.

(Example 2)
Offcuts with dimensions 25mm thick x 30mm wide x 1500mm long generated after cutting a steel plate with dimensions 25mm thick x 2200mm wide x 9000mm long from a hot-rolled SUS316 steel plate with dimensions 25mm thick x 2500mm wide x 10000mm long. are collected and lifted in units of 10 using a semi-gantry crane equipped with an electromagnetic lifting device 53 and the lifting device 1 shown in Figures 1 and 2, and transported from inside the cutting site to above the bag dedicated to scraps outside the cutting site. did. The dimensions and material of the hanging tool 1 are as described in the explanation of FIGS. 1 and 2, and the rated load is 250 kg. After transporting the scraps to the air above the bag, the excitation of the electromagnetic hanger 53 is stopped (released), and unloading is completed.
At this time, the operator completed the series of work safely and in a short time without any manual slinging work on the hanging load and the hanging tool 1. Thereafter, the electromagnetic hanger 53 was energized again and the work was repeated to finish cleaning up the scraps.

1 Hanging tool 10 Fixed top plate 11 Fixing part 11a Fixed top plate fixing part 11b Hanging load holding part fixing part 11c Fixing hole 20 Hanging load holding part 20a Fixed plate part 20b Fork part 30 Rotating top plate 31 Mounting plate part 31
31a Insertion hole 32 Hanging ring 32a Connection hole 40 Connection pin 51 Crane wire 52 Hook 53 Electromagnetic hanging tool (lifting magnet)
54 Support member 55 Hanging ring T Object W Wire

Claims (4)

A lifting device for lifting and transporting a non-magnetic object using a crane equipped with an electromagnetic lifting device,
A fixed top plate made of magnetic material,
a hanging load holding part that is fixed to a fixed part provided on the fixed top plate and holds the object;
a rotary top plate made of a magnetic material rotatably supported with respect to the fixed part and/or the fixed top plate so as to be able to change from a state overlapping with the fixed top plate to a state separated from the fixed top plate;
The rotating top plate is attracted to the electromagnetic hanger while overlapping with the fixed top plate, and when the electromagnetic hanger stops adhering, the rotating top plate is changed to a state separated from the fixed top plate. A hanging tool characterized by: The hanging tool according to claim 1, wherein the hanging load holding section is made of a non-magnetic material. The hanging device according to claim 1 or 2, wherein the rotating top plate is provided with a hanging ring connected to the electromagnetic hanging device by a wire. The hanging load holding part includes a fixing plate part fixed to the fixing part so as to extend to a side opposite to the side on which the fixed top plate is arranged, and a fixing plate part extending from an end of the fixing plate part to the fixing plate part. The hanger according to any one of claims 1 to 3, further comprising a fork portion that holds the object and extends perpendicularly to the fixed top plate and faces the fixed top plate. Ingredients.

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