KR102666594B1 - Lift Overrise Prevention Bar - Google Patents

Abstract

The present invention provides a lift overrise prevention bar that is installed on a mast and is provided with an upper frame, a lower frame, a frame support portion that prevents the lift from being separated, and a buffer portion that alleviates the shock caused by the lift.

Description

Lift Overrise Prevention Bar

The present invention relates to a lift overrise prevention bar, and more specifically, to a lift overrise prevention bar installed on a mast and provided with an upper frame, a lower frame, a frame support portion, and a buffer portion to relieve shock caused by a lift to prevent lift departure. will be.

Lifts are important equipment used in various industries to move, store, and work on goods. In particular, it helps you move heavy items smoothly in warehouses, factories, construction sites, etc. and easily raise or lower them to the desired height. A lift consists of a mast, an attached lift frame, and devices that raise and lower it.

However, existing lifts can pose a great risk if they malfunction, especially if the lift over-rises. For example, if the lift is raised too high, there is a risk of the lift and attached items falling. Additionally, if the lift rises excessively, the lift structure itself may become unstable and fall due to shock or vibration. These problems seriously threaten worker safety and can cause equipment damage or work delays.

Additionally, over-increasing the lift may cause damage to the mast. If the lift frame hits the top of the mast in an overlift condition, the mast may be damaged, which shortens the life of the lift and increases costs.

To solve this problem, a method to prevent excessive lift was needed. To this end, the present invention proposes a method for preventing excessive lift. This bar is fastened to the top and bottom of the mast to prevent the top and bottom of the lift from being separated.

Additionally, this bar can relieve the impact of hitting the lift through the shock absorber. These features contribute to improving lift safety and extending the life of the equipment.

The present invention was devised to solve the above problems, and the purpose of the present invention is to provide a lift overrise prevention bar equipped with an upper frame, a lower frame, and a frame supporter installed on a mast.

Another object of the present invention is to provide a lift overrise prevention bar provided with a shock absorber installed on the upper frame and lower frame to relieve shock.

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The object of the present invention is not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The lift overrise prevention bar according to an embodiment of the present invention to solve the above problem is fastened to the upper part of the mast to prevent upward separation as the lift goes up and down, and is fastened to the lower part of the mast to prevent the lift from moving upward. It includes a lower frame provided to prevent downward departure according to the raising and lowering of the mast, and a frame support unit provided to be fastened to correspond to the shape along the longitudinal direction of the mast, wherein the frame support unit supports the raising and lowering of the lift. , the upper frame may be arranged and fixed in a horizontal direction at the upper end, and the lower frame may be arranged and fixed in a horizontal direction at the lower end.

In one embodiment, the lift overrise prevention bar may include a buffer portion installed on the upper frame and the lower frame to relieve shock generated when the lift is in contact with the lift.

In one embodiment, the buffer unit includes a buffer cylinder inserted into the central portion of each of the upper frame and the lower frame, a buffer shaft inserted inward from the top of the buffer cylinder, and a peripheral portion of the buffer shaft to provide elastic force. A first buffer spring provided to generate an elastic force on the inner lower surface of the buffer cylinder, a spring compression member installed at the lower end of the buffer shaft and movable along the inside of the buffer cylinder, and a second buffer provided to generate an elastic force on the inner lower surface of the buffer cylinder. A spring, a spring support member installed on the upper part of the second buffer spring and supporting the second buffer spring to be compressed according to the lowering of the spring compression member, a first rotation installed on the upper end of the buffer shaft and rotatable A member, a frame support member installed on both sides of the first rotating member, a buffer plate having buffer protrusions extending downward at regular intervals on the rear surface, a second rotating member installed in the central portion of each rear surface of the buffer plate, the buffer plate A plate movable bracket fastened to both end portions to allow the buffer plate to move by impact, a rotating frame installed on each end of the plate movable bracket, and each of the plate movable brackets are connected, wherein the second rotating member is located at the central portion. A bracket support frame provided to be disposed, a spring fixing member installed at regular intervals on each of the upper frame and the lower frame, a spring support shaft installed upward from each of the spring fixing members, and an elastic force inserted into the circumference of the spring support shaft. A third buffer spring provided to generate a third buffer spring, a shaft fixing member inserted into the upper peripheral portion of the spring support shaft and provided to fix the spring support shaft while compressing the third buffer spring, installed at the upper end of the spring support shaft It may include a shock dispersion unit provided to disperse the shock transmitted to the buffer protrusion by the flow of the buffer plate.

In one embodiment, the shock dispersion unit includes an upper distribution plate provided in contact with the shock absorbing protrusion and having an upper ball groove formed on a rear surface, a lower distribution plate installed on the upper end of the spring support shaft and having a lower ball groove formed on the upper end, and the upper distribution plate. A distribution ball fitted by the ball groove and the lower ball groove and made of an elastic material, a corrugated shaft installed vertically toward the upper surface of the lower distribution plate at regular intervals on the rear surface of the upper distribution plate to disperse shock, Plate support shafts installed vertically toward the upper surface of the lower distribution plate at regular intervals on the rear surface of the upper distribution plate, distribution springs installed inside each of the plate support shafts to generate elastic force, and the buffer unit When an impact is transmitted by a lift, the buffer plate flows along the plate flow bracket, and each of the rotation frames is rotated by the first rotation member to be inserted along the plate flow bracket, and the buffer shaft is lowered. While doing so, the spring compression member compresses the second buffer spring through the spring support member using the elastic force of the first buffer spring to relieve the shock, and the shock is transmitted by the rotation of the buffer plate to the shock distribution unit. The shaft fixing member may further include a feature of alleviating the impact by transmitting and dispersing the impact while generating an elastic force of the third buffer spring.

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According to the present invention, a lift overrise prevention bar is provided, which is installed on a mast and is provided with an upper frame, a lower frame, a frame support portion, and a buffer portion that relieves shock caused by a lift to prevent lift separation.

Improved safety of the lift: The upper and lower frames are fastened to the mast to prevent the upper and lower parts of the lift from being separated, thereby reducing risks due to excessive lift. This helps ensure worker safety and prevent damage to items or equipment.

Mast protection: Prevents damage to the mast due to over-elevation. This extends the life of equipment and reduces maintenance costs, resulting in economic benefits.

Shock alleviation function: The shock absorbers installed on the upper and lower frames relieve the shock when the lift touches the frame. This more effectively prevents damage to the lift and mast, and further extends the life of the equipment.

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The effects according to the present invention are not limited to the details exemplified above, and further various effects are included within the present invention.

Figure 1 shows an overall embodiment of a lift overrise prevention bar according to the present invention.
Figure 2 shows an overall embodiment of the buffer portion of the lift overrise prevention bar according to the present invention.
Figure 3 shows the shock dispersion portion and surrounding structures of the lift overrise prevention bar according to the present invention.
Figure 4 shows an embodiment of the shock dispersion part of the lift overrise prevention bar according to the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the attached drawings. The embodiments described herein may be modified in various ways. Specific embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the attached drawings are only intended to facilitate understanding of the various embodiments. Therefore, the technical idea is not limited to the specific embodiments disclosed in the attached drawings, and it should be understood that all equivalents or substitutes included in the spirit and technical scope of the invention are included.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but these components are not limited by the above-mentioned terms. The above-mentioned terms are used only for the purpose of distinguishing one component from another.

In this specification, terms such as “comprise” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof. When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Meanwhile, a “module” or “unit” for a component used in this specification performs at least one function or operation. And the “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. Additionally, a plurality of “modules” or a plurality of “units” excluding a “module” or “unit” that must be performed on specific hardware or performed on at least one processor may be integrated into at least one module. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, when describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof is abbreviated or omitted.

Figure 1 shows an overall embodiment of a lift overrise prevention bar according to the present invention.

Referring to FIG. 1, the lift overrise prevention bar may include an upper frame 10, a lower frame 20, and a frame support portion 30.

The upper frame 10 may be fastened to the upper part of the mast to prevent upward separation as the lift goes up and down.

The lower frame 20 may be fastened to the lower part of the mast to prevent downward departure as the lift goes up and down.

The frame support portion 30 may be provided to be fastened to correspond to the shape and length of the mast along the longitudinal direction of the mast.

At this time, since the length of the mast usually ranges from several meters to tens of meters, it is preferable that the frame support part 30 is also provided in a shape of several meters to tens of meters in length corresponding to this.

In addition, the frame support unit 30 supports the raising and lowering of the lift, and is further characterized in that the upper frame 10 is arranged and fixed in the horizontal direction at the upper end, and the lower frame 20 is arranged and fixed in the horizontal direction at the lower end. It can be included.

Figures 2 to 4 show examples of the buffer portion of the lift overrise prevention bar according to the present invention.

Referring to FIGS. 2 to 4, the lift overrise prevention bar may include a buffer unit 100 installed on the upper frame 10 and the lower frame 20 to relieve the impact generated in contact with the lift. there is.

The buffer unit 100 includes a buffer cylinder 110, a buffer shaft 120, a first buffer spring 130, a spring compression member 140, a second buffer spring 150, a spring support member 160, and a first buffer spring 130. Rotating member 170, frame support member 180, buffer plate 190, second rotating member 200, plate moving bracket 210, rotating frame 220, bracket support frame 230, spring fixing member It may include (240), a spring support shaft 250, a third buffer spring 260, a shaft fixing member 270, and a shock dispersion unit 280.

The buffer cylinder 110 may be provided to be inserted into the central portion of each of the upper frame 10 and the lower frame 20.

The buffer shaft 120 may be provided to be inserted from the top of the buffer cylinder 110 toward the inside.

The first buffer spring 130 may be inserted into the circumference of the buffer shaft 120 to generate elastic force.

The spring compression member 140 may be installed at the lower end of the buffer shaft 120 and be movable along the inside of the buffer cylinder 110.

The second buffer spring 150 may be provided to generate elastic force on the inner lower surface of the buffer cylinder 110.

The spring support member 160 may be installed on the second buffer spring 150 to support and compress the second buffer spring 150 as the spring compression member 140 descends.

The first rotating member 170 may be installed at the upper end of the buffer shaft 120 and be rotatable.

The frame support member 180 may be installed on both sides of the first rotating member 170.

The buffer plate 190 may be provided with buffer protrusions 190a extending downward at regular intervals on its rear surface.

The second rotating member 200 may be installed at the center portion of the rear surface of each buffer plate 190.

The plate moving bracket 210 may be fastened to both ends of the buffer plate 190 so that the buffer plate 190 can move by impact.

The rotating frame 220 may be installed on each end of the plate moving bracket 210.

The bracket support frame 230 connects each of the plate moving brackets 210 and may be provided so that the second rotating member 200 is disposed at the center.

The spring fixing members 240 may be installed at regular intervals on each of the upper frame 10 and the lower frame 20.

The spring support shaft 250 may be installed upward in each of the spring fixing members 240.

The third buffer spring 260 may be inserted into the circumference of the spring support shaft 250 to generate elastic force.

The shaft fixing member 270 may be inserted into the upper peripheral portion of the spring support shaft 250 and may be provided to fix the spring support shaft 250 while compressing the third buffer spring 260.

The shock dispersion unit 280 may be installed at the upper end of the spring support shaft 250 to disperse the shock transmitted to the buffer protrusion 190a by the flow of the buffer plate 190.

In addition, the shock distribution unit 280 may include an upper distribution plate 281, a lower distribution plate 282, a distribution ball 283, a corrugated shaft 284, a plate support shaft 285, and a distribution spring 286. You can.

The upper distribution plate 281 may be provided in contact with the buffering protrusion 190a, and may be provided such that an upper ball groove 281a is formed on the rear surface.

The lower distribution plate 282 may be installed at the upper end of the spring support shaft 250, and may be provided so that a lower ball groove 282a is formed at the upper end.

The distribution ball 283 is inserted into the upper ball groove 281a and the lower ball groove 282a and may be made of an elastic material.

The corrugated shaft 284 may be installed vertically toward the upper surface of the lower distribution plate 282 at regular intervals on the rear surface of the upper distribution plate 281 to disperse impact.

The plate support shaft 285 may be installed vertically toward the upper surface of the lower distribution plate 282 at regular intervals on the rear surface of the upper distribution plate 281.

The distribution spring 286 may be installed inside each of the plate support shafts 285 to generate elastic force.

The assembly relationship and effect of the embodiment according to the above configurations are described in detail as follows.

In the buffer unit 100, it is installed on the rear surface of the upper frame 10 and the upper surface of the lower frame 20.

The assembly relationship to be described below is explained based on the lower frame 20, and the assembly relationship for the upper frame 10 is also the same below, so it is omitted to avoid redundant explanation.

The shock absorbing cylinder 110 is inserted into the central part of the lower frame 20 in a vertical direction.

A buffer shaft 120 is inserted into the upper part toward the inside of the buffer cylinder 110.

At this time, the first buffer spring 130 is inserted into the lower portion of the peripheral portion of the buffer shaft 120, and the spring compression member 140 is assembled to the lower portion.

Meanwhile, a second buffer spring 150 and a spring support member 160 are assembled on the inner lower part of the buffer cylinder 110.

The following shape is assembled on the upper part of the buffer shaft 120.

The first rotating member 170 is assembled at the center of the frame support member 180, and the first rotating member 170 is fastened to the upper end of the buffer shaft 120, and is attached to both sides of the frame support member 180. The rotating frames 220 are respectively inserted toward.

Meanwhile, the following shape is installed on the upper surface of the lower frame 20 at a certain distance from the shape in which the shock absorbing cylinder 110 is assembled.

Plate flow brackets 210 are fastened to both ends of the buffer plate 190 as shown in the drawing.

At this time, the bracket support frame 230 is assembled to connect each plate floating bracket 210.

The second rotating member 200 is installed in the assembled shape at the center of the back of the buffer plate 190.

At this time, the second rotating member 200 may be coupled to the central portion of the bracket support frame 230 to rotate the bracket support frame 230.

At this time, each rotating frame 220 is inserted into one end of the plate moving bracket 210.

Meanwhile, buffering protrusions 190a are formed downward on both sides of the rear surface of the buffer plate 190 and are disposed in contact with the shape shown below.

A spring support shaft 250 with a third buffer spring 260 inserted into the peripheral portion is assembled in a vertical direction around the spring fixing member 240.

A shaft fixing member 270 is inserted into the upper peripheral portion of the spring support shaft 250, and a shock dispersion portion 280 is assembled to the upper portion of the spring support shaft 250.

In the shock distribution unit 280, a plate support shaft 285 with distribution springs 286 built into both sides of the upper surface relative to the lower distribution plate 282 is assembled in the vertical direction, and the plate support shaft 285 and Corrugated shafts 284 are vertically assembled on both sides of the upper surface of the lower distribution plate 282 at regular intervals as shown in the drawing.

The upper distribution plate 281 is assembled so that the upper portions of each plate support shaft 285 and corrugated shaft 284 are connected, and the distribution balls 283 are assembled to fit the upper ball groove 281a and lower ball groove 282a. .

In one embodiment, the shock absorber 100 can alleviate the shock when the shock is transmitted by the operation of the lift.

In one embodiment, the buffer plate 190 may flow or slide along the plate flow bracket 210 due to impact.

In one embodiment, each of the rotating frames 220 can be rotated by the first rotating member 170 and inserted along the plate moving bracket 210.

In one embodiment, the buffer plate 190 can be rotated in the left and right directions by the second rotation member 200.

In one embodiment, as the buffer shaft 120 is lowered, the spring compression member 140 compresses the second buffer spring 150 through the spring support member 160 by the elastic force of the first buffer spring 130, thereby compressing the second buffer spring 150 with elastic force. It can alleviate shock.

In one embodiment, the shock may be distributed by the shock protrusion 190a to the shock dispersion unit 280 by rotation of the shock plate 190.

In one embodiment, the upper distribution plate 281 may then distribute the impact through the elastic force of distribution springs 286 within each corrugated shaft 284 and plate support shaft 285.

In one embodiment, the shock transmitted to the upper distribution plate 281 causes the distribution ball 283 to rotate the upper distribution plate 281 at various angles to distribute the impact to the lower distribution plate 282. .

In one embodiment, the shaft fixing member 270 may descend along the circumference of the spring support shaft 250 to generate elastic force of the third buffer spring 260 to alleviate the impact.

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Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

Upper frame (10)
Lower frame (20)
Frame support (30)
Buffer part (100)
Shock Cylinder (110)
Shock shaft (120)
First buffer spring (130)
Spring compression member (140)
Second buffer spring (150)
Spring support member (160)
1st rotating member (170)
Frame support member (180)
Buffer plate (190)
Buffering protrusion (190a)
Second rotating member (200)
Plate floating bracket (210)
Rotating frame (220)
Bracket support frame (230)
Spring fixing member (240)
Spring support shaft (250)
Third buffer spring (260)
Shaft fixing member (270)
Shock dispersion unit (280)
Top Dispersion Plate (281)
Upper ball groove (281a)
Lower distribution plate (282)
Lower ball groove (282a)
Dispersion Ball (283)
Corrugated Shaft(284)
Plate support shaft (285)
Dispersion Spring(286)

Claims (3)

An upper frame fastened to the upper part of the mast to prevent upward separation as the lift rises and falls;
A lower frame fastened to the lower part of the mast to prevent downward departure as the lift goes up and down;
A frame support provided to be fastened to correspond to the shape along the longitudinal direction of the mast;
Including,
The frame support part,
While supporting the raising and lowering of the lift,
The upper frame is placed and fixed in the horizontal direction at the upper end,
In the lift overrise prevention bar, which further includes a feature in which the lower frame is arranged and fixed in a horizontal direction at the lower end,
a shock absorber installed on the upper frame and the lower frame to relieve shock generated when contacting the lift;
Including,
The buffer part,
a shock absorbing cylinder inserted into the central portion of each of the upper frame and the lower frame;
a shock absorbing shaft inserted toward the inside from an upper portion of the shock absorbing cylinder;
a first buffer spring inserted into the circumference of the buffer shaft to generate elastic force;
a spring compression member installed at the lower end of the buffer shaft and movable along the inside of the buffer cylinder;
a second buffer spring provided to generate elastic force on the inner lower surface of the buffer cylinder;
a spring support member installed on an upper portion of the second buffer spring and supporting the second buffer spring to be compressed as the spring compression member descends;
a first rotating member installed at the upper end of the buffer shaft and rotatably provided;
Frame support members installed on both sides of the first rotating member;
A buffer plate having cushioning protrusions extending downward at regular intervals on the rear surface;
a second rotating member installed at the center of the rear surface of each of the buffer plates;
Plate moving brackets fastened to both ends of the buffer plate to allow the buffer plate to flow due to impact;
a rotating frame installed on each end of the plate moving bracket;
a bracket support frame connecting each of the plate moving brackets so that the second rotating member is disposed at the center;
Spring fixing members installed at regular intervals on each of the upper frame and the lower frame;
a spring support shaft installed upwardly from each of the spring fixing members;
a third buffer spring inserted into the circumference of the spring support shaft to generate elastic force;
a shaft fixing member inserted into an upper peripheral portion of the spring support shaft to fix the spring support shaft while compressing the third buffer spring;
a shock dispersion unit installed on the upper end of the spring support shaft to disperse shock transmitted to the buffer protrusion by the flow of the buffer plate;
Including,
The shock dispersion unit,
an upper distribution plate provided in contact with the buffering protrusion and having an upper ball groove formed on its rear surface;
a lower distribution plate installed on the upper end of the spring support shaft and having a lower ball groove formed on the upper end;
a distribution ball fitted into the upper ball groove and the lower ball groove and made of an elastic material;
corrugated shafts installed vertically toward the upper surface of the lower distribution plate at regular intervals on the rear surface of the upper distribution plate to disperse shock;
Plate support shafts installed vertically toward the upper surface of the lower distribution plate at regular intervals on the rear surface of the upper distribution plate;
Distribution springs installed inside each of the plate support shafts to generate elastic force;
Including,
The buffer part,
When the shock is transmitted by the lift,
As the buffer plate flows along the plate flow bracket,
Each of the rotating frames is rotated by the first rotating member and inserted along the plate moving bracket,
As the buffer shaft descends, the spring compression member compresses the second buffer spring through the spring support member using the elastic force of the first buffer spring to relieve the shock,
As the shock plate rotates, the shock protrusion transfers the shock to the shock dispersion unit to disperse the shock.
The lift overrise prevention bar further includes a feature in which the shaft fixing member generates an elastic force of the third buffer spring to relieve impact. delete delete