KR102282065B1 - Vertical Transport Systems - Google Patents

Abstract

A vertical conveying system is disclosed. A vertical transport system according to an embodiment of the present invention includes a carriage body for supporting an object to be transported, and a carriage lifting unit connected to the carriage body, the carriage being lifted between a plurality of floors; a lifter connected to one side of the carriage elevating unit to elevate the carriage; and a carriage elevating unit traveling frame forming a carriage elevating unit travel path through which the carriage elevating unit travels, and a counterweight elevating unit traveling path connected to the carriage elevating unit and elevating and elevating the counterweight elevating unit moving up and down in the opposite direction to the carriage elevating unit. It includes a combination type mast frame in which the traveling frame of the counterweight lifting unit to form is arranged side by side in the width direction of the carriage body.

Description

Vertical Transport Systems

The present invention relates to a vertical conveying system, and more particularly, it is possible to significantly reduce the installation area of the vertical conveying system, and furthermore, vertical conveyance that can be installed in various forms according to the desired installation height and installation form by a combination of frames It's about the system.

The vertical conveying system refers to an apparatus used when conveying articles over a plurality of layers, FIG. 1 is a schematic view of a conventional vertical conveying system, and FIG. 2 is a perspective view showing the mast frame portion of FIG. am.

As shown in detail in FIG. 1, the vertical conveying system 1' is provided with a booth (Booth, 3) which is a passage for conveying the conveyed object 2 over a plurality of floors, and a carriage 100 therein. '), a lifter 200', and a mast frame 300' are provided to transport the object 2 to a desired position.

Briefly describing the operation of the lifter 200 ′ with reference to FIGS. 1 and 2 , the driving unit 210 operates to move the timing belt 220 connected to one side of the carriage lifting unit 130 ′ in a desired direction. By moving, the carriage 100' including the carriage lifting unit 130' and the carriage body 110' can be transported to a desired floor.

At this time, the mast frame 300' is disposed through a connection passage P formed between two adjacent layers up and down over a plurality of layers, and the carriage lifting unit 130' and the counterweight lifting unit 230' ) serves as a rail for guiding so that it can be raised and lowered without shaking, so the carriage elevating unit 130' and the counterweight elevating unit 230' inside the mast frame 300' are used to guide the elevating and lowering. A carriage elevating unit traveling passage (P1', see FIG. 2) and a counterweight lifting unit traveling passage (P2', see FIG. 2) are formed.

However, in such a conventional vertical conveying system, in consideration of the weight distribution between the carriage body and the counterweight, as shown in FIGS. 1 and 2 , the carriage elevating unit travels based on the inner center of the mast frame 300 ′. It is common that the passage P1' is located in the direction toward the carriage body 110' and the counterweight lifting unit traveling passage P2' is located on the opposite side.

Since this conventional mast frame has a shape that protrudes in a direction away from the carriage body, the mast frame and lifter are used as many as the number of carriages in order to provide a vertical conveying system for conveying a plurality of carriages using the conventional mast frame. When additionally installed, there is a problem in that the installation area of the vertical transfer system becomes too large.

Republic of Korea Patent Publication No. 10-2016-0026240 (2016.03.09.)

Therefore, the technical problem to be achieved by the present invention is to provide a vertical conveying system that can significantly reduce the installation area of the vertical conveying system and can be installed in various forms according to the desired installation height and installation shape by a combination of frames.

According to an aspect of the present invention, there is provided a carriage comprising: a carriage body for supporting an object to be transported; a carriage elevating unit connected to the carriage body, the carriage being lifted between a plurality of floors; a lifter connected to one side of the carriage elevating unit to elevate the carriage; and a carriage elevating unit traveling frame forming a traveling passage of the carriage elevating unit through which the carriage elevating unit travels, and a counterweight elevating unit connected to the carriage elevating unit and elevating and elevating the counterweight elevating unit in a vertical direction opposite to that of the carriage elevating unit. A vertical conveying system can be provided, wherein the counterweight lifting unit traveling frame forming the traveling passage includes a combined mast frame arranged side by side in the width direction of the carriage body.

The carriage elevating unit traveling frame includes three main plates disposed adjacent to each other and surrounding the carriage elevating unit traveling path to form the carriage elevating unit traveling path therein, and another adjacent to the outer wall of the main plate. A coupling portion may be formed so as to be mutually coupled to the frame.

The carriage elevating unit traveling frame may further include a pair of rail plates coupled to both free ends of the three main plates disposed adjacent to each other to contact and support the traveling wheels of the carriage elevating unit.

The carriage elevating unit traveling frame, the three main plates and a pair of rail plates may be integrally provided by extrusion molding.

The carriage elevating unit traveling frame may be provided by vertically stacking and combining unit carriage elevating unit traveling frames provided by a predetermined length.

Further comprising a power cable connected to the carriage body, the pair of combined mast frames are coupled with their backs facing each other to provide a cable power dual mast frame, and a pair of the carriages of the cable power dual mast frame are raised and lowered A pair of the carriage lifting and lowering units may each travel in the unit traveling passage.

The combined mast frame further includes a non-contact power supply arrangement frame disposed on one side of the carriage elevating unit traveling frame, in which a non-contact power supply for supplying power to the carriage body in a non-contact manner is disposed, the carriage elevating unit A traveling frame may be disposed in the center, and the counterweight lifting unit traveling frame and the non-contact power supply arrangement frame may be disposed on both sides of the carriage lifting unit traveling frame, respectively.

A pair of combined mast frames are coupled with their backs facing each other to provide a non-contact power dual mast frame, and a pair of carriage elevating units are provided in the driving passage of the pair of non-contact power dual mast frames, respectively. can drive

The carriage body may include a carriage support frame coupled to the carriage lifting unit; and a horizontal transfer unit coupled to the carriage support frame to transfer the object to be transported in a horizontal direction.

The carriage body may further include a carriage body frame in which a pair of the carriage support frames are coupled to each other while being spaced apart from each other in the vertical direction, and the carriage lifting unit may be coupled to the carriage body frame.

The carriage elevating unit may include: a main body module disposed in the carriage elevating unit traveling passage; and at least one wheel module coupled to the main body module, the at least one wheel module being in contact with the elevating unit traveling frame to guide elevating, wherein the at least one wheel module is provided without taking the main body module out of the carriage elevating unit traveling passage. The at least one wheel module may be coupled and detachably coupled to the body module in the direction of the carriage body so that the at least one wheel module can be taken out of the carriage elevating unit traveling passage.

The at least one wheel module may include: a driving wheel module having at least one driving wheel in contact with an inner wall of the combined mast frame and traveling along the combined mast frame; and a guide wheel module including at least one guide wheel for guiding the lifting and lowering of the carriage elevating unit in contact with the inner wall of the combination type mast frame in a direction intersecting the inner wall with which the traveling wheel is in contact.

The body module may include: a traveling wheel module coupling part to which the traveling wheel module is slidably coupled in the direction of the carriage body; and a guide wheel module coupling part provided at one side of the driving wheel module coupling part and slidingly coupled to the guide wheel module in the direction of the carriage body, wherein the driving wheel module coupling part has a guide adapter for guiding the sliding coupling of the driving wheel module can be provided.

The driving wheel module coupling portion has a U-shape with a concave portion formed toward the carriage body, and the traveling wheel module includes: a traveling wheel support block coupled to the concave portion; and a traveling wheel coupled to the traveling wheel support block to be relatively rotatable.

The driving wheel module may include a first driving wheel module and a second driving wheel module that are individually coupled to and separated from the driving wheel module coupling unit.

The guide wheel module coupling part is coupled to an upper portion of the driving wheel module coupling part, and the guide wheel module includes: a U-shaped guide wheel support block coupled while surrounding the guide wheel module coupling part; and at least one guide wheel rotatably coupled to the guide wheel support block.

Embodiments of the present invention can have a compact structure by arranging and combining the carriage elevating unit traveling frame and the counterweight elevating unit traveling frame in various ways, so that the installation area of the vertical conveying system can be greatly reduced, and furthermore, the combination of the frame It can be installed in various forms according to the desired installation height and installation type.

In addition, by providing an elevating unit having a wheel module that is coupled and detachably coupled from the main body module to the carriage body direction, without taking the main body module out of the elevating unit traveling path, only the wheel module can be separated and taken out of the elevating unit traveling path. Therefore, maintenance work such as replacing the wheel can be performed simply and easily.

1 is a view schematically showing a conventional vertical conveying system.
FIG. 2 is a perspective view illustrating a part of the mast frame of FIG. 1 .
3 is a perspective view schematically illustrating a combination type mast frame according to a first embodiment of the present invention.
4 is a plan view of the combined mast frame of FIG. 3 .
5 is a perspective view illustrating the carriage lifting unit of FIG. 3 .
6 is a view illustrating a state in which the traveling wheel module and the guide wheel module are separated from the main body module of the carriage lifting unit of FIG. 5 .
7 is a plan view of a combination type mast frame according to a second embodiment of the present invention.
8 is a plan view of a combined mast frame according to a third embodiment of the present invention.
9 is a plan view of a combination type mast frame according to a fourth embodiment of the present invention.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings illustrating preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by describing preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in each figure indicate like elements.

3 is a perspective view schematically showing a combination type mast frame according to a first embodiment of the present invention, FIG. 4 is a plan view of the combination type mast frame of FIG. 3, and FIG. 5 is a perspective view showing the carriage lifting unit of FIG. , FIG. 6 is a view showing a state in which the driving wheel module and the guide wheel module are separated from the main body module of the carriage elevating unit of FIG. 5 .

As shown in these drawings, the vertical transport system according to an embodiment of the present invention includes carriages 100a and 100b, lifters 200a and 200b, and a combined mast frame 300A.

First, the carriage 100a supports the object to be conveyed and serves to convey the object to be conveyed by raising/lowering, ie, raising and lowering, between the plurality of floors.

The carriage 100a, as shown in detail in FIG. 3, includes a carriage body 110a and a carriage lifting unit 130a.

The carriage body 110a serves to support the object to be transported, and the carriage elevating unit 130a is coupled to one side of the carriage body 110a and is lifted by the drive unit 210 of the lifter (refer to FIG. 1 ) while the carriage body 110a is lifted. ) to move up and down together.

The carriage body 110a and the carriage lifting unit 130a will be described in detail later.

Next, the lifter 200a is connected to one side of the carriage elevating unit 130a as described above and serves to elevate the carriage 100a, a driving unit 210 (refer to FIG. 1), a timing belt 220a and , and a counterweight lifting unit (230a).

The driving unit 210 (refer to FIG. 1) is generally connected to the pulley 240 (refer to FIG. 1) to rotate the pulley, and by moving the timing belt 220 by rotation of the pulley, the carriage 100a can be raised and lowered. do.

However, the present invention is not limited thereto, and in addition to a combination of a pulley and a timing belt, it may be combined in various forms connected to one side of the carriage lifting unit 130a to elevate the carriage 100a.

The counterweight elevating unit 230a is connected to the carriage elevating unit 130a and the timing belt 220a to move the carriage elevating unit 130a while elevating in the opposite direction to the carriage elevating unit 130a. serves to reduce

On the other hand, the combined mast frame according to the first embodiment of the present invention is provided with a non-contact power dual mast frame (300A), and as shown in detail in FIGS. 3 and 4, the carriage elevating unit traveling frame (310a, 310b) and , and a counterweight lifting unit traveling frame (330a, 330b), and a non-contact power supply arrangement frame (350a, 350b).

As described above, the non-contact power dual mast frame 300A, which is a combination type mast frame, is disposed through a connection passage formed between two layers adjacent up and down over a plurality of layers, and the carriage lifting unit 130a and the counterweight lifting and lowering. It serves as a rail that guides the unit 230a so that it can ascend and descend without shaking.

First, referring to FIGS. 3 and 4 , the parts related to the carriage 100a disposed on the front part will be described in detail. The carriage elevating unit traveling frame 310a, the counterweight elevating unit traveling frame 330a, and the non-contact power source The supply device arrangement frame (350a) is arranged side by side in the width direction of the carriage body (130a).

At this time, the carriage elevating unit traveling frame 310a is arranged in the center, and the counterweight elevating unit traveling frame 330a and the non-contact power supply arrangement frame 350a are respectively arranged on both sides of the carriage elevating unit traveling frame 310a. .

In this arrangement, compared with the conventional mast frame shown in FIGS. 1 and 2 , the carriage elevating unit running passage P1a and the counterweight lifting unit running passage P3a are arranged side by side in the width direction of the carriage body 130a. There is a difference in point.

In other words, the conventional mast frame has a shape in which the carriage body, the carriage elevating unit running path, and the counterweight elevating unit running path are arranged in a straight line so that the mast frame protrudes in a direction away from the carriage body, so the carriage body and the mast Although the area surrounding the frame is large, the combined mast frame according to the present invention has a shape in which the carriage body, the carriage elevating unit running passage, and the counterweight lifting unit running passage are arranged in a L-shape, so that the combined mast frame is in close contact with the carriage body. Therefore, the area surrounding the carriage body and the mast frame is greatly reduced.

This effect can be further increased when applied to a dual carriage system that can individually elevate the carriage 100a disposed on the front part and the carriage 100b disposed on the rear part, and can be arranged in a more compact structure. Therefore, it is possible to further reduce the installation area of the vertical conveying system.

That is, the carriage elevating unit traveling frame 310a, the counterweight elevating unit traveling frame 330a and the non-contact power supply arrangement frame 350a are arranged side by side is referred to as a front side combination type mast frame, and the carriage elevating unit traveling frame 310b ), counterweight lifting unit traveling frame (330b) and non-contact power supply arrangement frame (350b) are arranged side by side as a rear combination type mast frame, the front side combination type mast frame and the rear side side combination type mast frame are combined with their backs facing each other This is called a non-contact power dual mast frame (300A).

A pair of carriage elevating units 130a and 130b respectively travel in the pair of carriage elevating unit travel passages P1a and P1b of the non-contact power dual mast frame 300A, and a pair of counterweight elevating unit travel passages P3a , P3b), a pair of counterweight lifting units 230a and 230b run, respectively, and a pair of contactless power supply units 400a and 400b are arranged on the pair of non-contact power supply arrangement frames 350a and 350b. .

The carriage elevating unit traveling frame 310a serves to form a carriage elevating unit traveling passage P1a through which the carriage elevating unit travels, and includes a main plate 311 and a rail plate 312 .

The main plate 311 includes three main plates 311 disposed adjacent to each other so as to surround the carriage elevating unit running passage P1a in order to form a carriage elevating unit running passage P1a therein, and the main plate ( 311) is formed with a coupling portion (not shown) so as to be mutually coupled to other adjacent frames.

By providing a coupling portion, it is possible to simply couple the counterweight lifting unit traveling frame 330a, the non-contact power supply arrangement frame 350a, and the carriage lifting unit traveling frame 310b, which are disposed adjacent to each other, and these coupling portions are bolts and nuts. It may be formed in various forms so as to couple various types of coupling members, including

The rail plate 312 is coupled to both free ends of the three main plates 311 disposed adjacent to each other to contact and support the traveling wheels 173 (refer to FIGS. 5 and 6) of the carriage elevating unit 130a. do.

In the carriage elevating unit traveling frame 310a having such a shape, the three main plates 311 and a pair of rail plates 312 are individually manufactured and provided by combining, as well as integrally provided by extrusion molding. it could be

In addition, the carriage elevating unit traveling frame 310a may be provided by stacking and coupling unit carriage elevating unit traveling frames provided by a predetermined length up and down, and by stacking and bonding the unit carriage elevating unit traveling frames in this way, depending on the desired conveyance height There is an advantage in that the vertical conveying system can be provided at various heights.

On the other hand, the counterweight elevating unit traveling frame 330a is connected to the carriage elevating unit 130a, and the counterweight elevating unit 230a, which elevates and lowers in the vertical direction opposite to the carriage elevating unit 130a, travels through the counterweight elevating unit traveling passage P3a. It serves to form a, and the carriage elevating unit traveling frame (310a) and its structure described so far are provided almost the same.

On the other hand, the non-contact power supply arrangement frame (350a) is disposed on one side of the carriage elevating unit traveling frame (310a), the carriage body (110a, see Fig. 3) non-contact power supply for supplying power in a non-contact manner (400a, Fig. 3) is the place to be placed.

In the vertical transport system, the carriage body 110a is only schematically shown in FIG. 3, but various devices such as a device for horizontally transporting the transported object in order to enter/exit and a sensor for sensing the position of the transported object are arranged, In order to supply power to these devices, power is generally supplied by connecting a power cable (not shown) to the carriage body.

However, when a power cable (not shown) is connected to the carriage body 110a, since the connected power cable moves up and down together with the carriage body, the higher the desired conveyance height, the longer the length of the connected power cable becomes, and the length of the power cable Since the volume and weight increase, there is a problem that the height of the vertical conveying system that can be installed is physically limited.

Therefore, according to the first embodiment of the present invention, a non-contact power supply arrangement frame (350a) is provided and a non-contact power supply device for supplying power to the carriage body in a non-contact manner (see Fig. 3) is arranged. By doing so, it is possible to supply power to the carriage body 110a in a non-contact manner without the need to physically connect a separate power cable, so that movement of the power cable connected to the carriage body can be excluded, and the length, volume and It is possible to solve the problem that the height of the vertical conveying system that can be installed is limited according to the increase in weight.

Hereinafter, the carriage body 110 and the carriage lifting unit 130 will be described with reference to FIGS. 5 and 6 .

First, the carriage body 110, as shown in detail in FIG. 5, a carriage body frame 111 coupled to the carriage lifting unit 130, and a carriage support frame 112 coupled to the carriage body frame 111 and , and a horizontal transfer unit (not shown) coupled to the carriage support frame 112 to transfer the object to be transported in the horizontal direction.

In this embodiment, the carriage support frame 112 is provided as a pair and coupled to the carriage body frame 111 while being spaced apart from each other in the vertical direction. By having such a structure, there is an advantage in that the object to be transported can be loaded in two stages.

However, the present invention is not limited thereto, and various changes may be made so that it can be loaded in one or more stages in consideration of the weight or volume of the object to be transported.

Next, the carriage elevating unit 130 is coupled to the main body module 150 and the main body module 150 disposed in the carriage elevating unit traveling passages (P1a, P1b, see FIG. 4), as shown in detail in FIG. 6 . Doedoe includes at least one wheel module 170 for guiding the lift in contact with the carriage elevating unit traveling frame (310a, 310b, see FIG. 4).

In addition, the at least one wheel module 170 includes driving wheel modules 171a and 171b and a guide wheel module 175 .

The carriage elevating unit 130 according to an embodiment of the present invention includes at least one wheel module 170 without taking out the main body module 150 from the carriage elevating unit traveling passages (P1a, P1b, see FIG. 4). At least one wheel module 170 is coupled to and detachably from the body module 150 in the direction of the carriage body 110 (refer to FIG. 5) so that it can be taken out of the driving passage (P1a, P1b, see FIG. 4). .

Among the conventional vertical conveying systems, the carriage elevating unit in which the traveling wheel is exposed to the outside of the rail has the advantage of convenient maintenance work such as replacing the wheel. However, due to the characteristics of the vertical conveying system, the lifter is not exposed to the outside. It needs to be configured, and in this case, there is a problem in that the maintenance work becomes complicated.

Accordingly, the carriage lifting unit 130 according to an embodiment of the present invention separates only the travel wheel modules 171a and 171b or the guide wheel module 175 without taking the main body module 150 out of the carriage elevating unit travel passage to separate the carriage. Since the elevating unit can be taken out of the driving passage, there is an advantage that maintenance work such as replacing the wheel can be carried out easily.

In this way, the main body module 150 includes a driving wheel module coupling part 151 and a guide wheel module coupling part 155 so that only the driving wheel modules 171a and 171b or the guide wheel module 175 can be separated and coupled. .

The driving wheel module coupling part 151 is a place where the driving wheel module 171 is slidably coupled in the direction of the carriage body 110 (see FIG. 5 ), and has a U-shape in which a recess is formed toward the carriage body 110 .

At this time, a guide adapter 152 for guiding the sliding coupling of the driving wheel modules 171a and 171b is provided on one side of the concave portion.

The guide adapter 152 is formed with a guide protrusion and is fitted with the guide grooves of the traveling wheel support blocks 172a and 172b of the traveling wheel modules 171a and 171b to guide the sliding coupling.

The guide wheel module coupling part 155 is provided on one side of the driving wheel module coupling part 151 and is a place where the guide wheel module 175 is slidably coupled in the direction of the carriage body 110 (see FIG. 5 ), and in this embodiment, the guide The wheel module coupling part 155 is provided on the driving wheel module coupling part 151 .

On the other hand, the driving wheel modules 171a and 171b come into contact with the inner wall of the carriage elevating unit traveling frame and serve to travel along the carriage elevating unit traveling path, and include at least one traveling wheel 173a and 173b. In detail, the inner wall of the carriage elevating unit traveling frame in contact with the traveling wheels 173a and 173b is the inner wall of the rail plate 312 (refer to FIG. 4) or the main plate 311 (refer to FIG. 4) facing the rail plate.

As shown in detail in FIG. 6 , the driving wheel modules 171a and 171b include driving wheel support blocks 172a and 172b and driving wheel support blocks 172a and 172b coupled to the concave portion of the driving wheel module coupling part 151 . ) and a travel wheel (173a, 173b) coupled to the relative rotation.

According to an embodiment of the present invention, the driving wheel modules 171a and 171b include a first driving wheel module 171a and a second driving wheel module 171b that are individually coupled to and separated from the driving wheel module coupling unit 151 . designed to include

In this way, by providing the driving wheel modules 171a and 171b that are individually coupled and separated, there is an advantage that the driving wheels 173a and 173b can be individually maintained, but the present invention is not limited thereto. One driving wheel module in which four driving wheels are combined may be provided.

On the other hand, the guide wheel module 175 contacts the inner wall of the carriage elevating unit traveling frame in a direction intersecting the inner wall in contact with the driving wheels 173a and 173b to guide the elevating and lowering of the carriage elevating unit 130, In detail, the guide wheel 177 simultaneously contacts two inner walls in a direction intersecting with the rail plate 312 (refer to FIG. 4 ), which is the inner wall in contact with the traveling wheels 173a and 173b, and thus the carriage elevating unit 130. It can guide so that it can go up and down without this shaking.

The guide wheel module 175 includes at least one U-shaped guide wheel support block 176 coupled while surrounding the guide wheel module coupling part 155 and at least one relatively rotatably coupled to the guide wheel support block 176 . and a guide wheel 177 .

In the present embodiment, four guide wheels 177 having a size smaller than that of the driving wheels 173a and 173b are provided, but the present invention is not limited thereto, and guide wheels of various shapes and numbers according to the weight and size of the carriage are provided. this could be provided.

When describing the process of separating the driving wheel modules 171a and 171b or the guide wheel module 175 from the main body module 150 of the carriage lifting unit 130 having such a structure, first, the carriage lifting unit 130 moves the carriage lifting and lowering. It moves to the maintenance section for the maintenance of the unit driving frame.

In general, the maintenance section is located at the bottom of the carriage elevating unit traveling frame. In this section, there is no rail plate and only three main plates exist, so that the traveling wheel is not blocked by the rail plate.

Therefore, in the state where the carriage elevating unit is positioned in this maintenance section, the traveling wheel modules 171a and 171b or the guide wheel module 175 can be simply separated from the main body module 150 in the direction of the carriage body, so that the main body module ( 150), it is possible to easily perform maintenance work such as wheel replacement even in a state in which the carriage elevating unit is disposed inside the traveling passage.

So far, the carriage elevating unit 130 has been described, but even in the case of the counterweight elevating unit 230a (see FIG. 3 ), it has an almost similar structure except for the difference that it is coupled with a counterweight (not shown) rather than the carriage body 110. there is. Therefore, even in the case of the counterweight lifting unit 230a, without taking the main body module out of the counterweight lifting unit driving frame (P3a, see FIGS. 3 and 4), only the driving wheel module or the guide wheel module can be separated and taken out of the counterweight lifting unit driving passage. Therefore, the advantage of being able to easily perform maintenance work such as replacing the wheel is the same.

As described above, according to the present embodiment, by arranging and combining the carriage elevating unit traveling frame and the counterweight elevating unit traveling frame in various ways, it can have a compact structure, thereby greatly reducing the installation area of the vertical conveying system, and furthermore, the frame It can be installed in various shapes according to the desired installation height and installation type by combination.

In addition, by providing an elevating unit having a wheel module that is coupled and detachably coupled from the main body module to the carriage body direction, without taking the main body module out of the elevating unit traveling path, only the wheel module can be separated and taken out of the elevating unit traveling path. Therefore, maintenance work such as replacing the wheel can be performed simply and easily.

7 is a plan view showing a second embodiment of the combination type mast frame according to the present invention, the combination type mast frame according to the second embodiment is provided with a non-contact power supply single mast frame (300B).

That is, the non-contact power single mast frame 300B is a combination type mast frame in which the carriage elevating unit traveling frame 310a described above, the counterweight elevating unit traveling frame 330a and the non-contact power supply arrangement frame 350a are arranged side by side. And, unlike the first embodiment, it can be used in a single-carriage-type vertical conveying system capable of elevating only one carriage.

8 is a plan view showing a third embodiment of the combination type mast frame according to the present invention, the combination type mast frame according to the third embodiment is provided with a cable power dual mast frame (300C).

The carriage elevating unit running frame 310a and the counterweight elevating unit running frame 330a are arranged side by side is referred to as a front combination type mast frame, and the carriage elevating unit running frame 310b and the counterweight elevating unit running frame 330b are side by side. If it is called a rear combination type mast frame, the combination of the front side combination type mast frame and the rear side combination type mast frame with their backs to each other is called a cable power dual mast frame (300C).

The cable power dual mast frame 300C having this structure does not need to install a contactless power supply because the required height of the vertical transport system to be installed is not high, and it is better to include a power cable (not shown) connected to the carriage body. It can be used in an efficient vertical conveying system.

In addition, since a pair of carriage elevating units each run in the pair of carriage elevating unit traveling passages P1a and P1b of the cable power dual mast frame 300C, the pair of carriages can be individually moved while occupying a minimum area. be able to elevate.

9 is a plan view showing a fourth embodiment of the combination type mast frame according to the present invention, the combination type mast frame according to the fourth embodiment is provided as a cable power single mast frame (300D).

That is, the cable power single mast frame 300D is a combined mast frame in which the carriage elevating unit traveling frame 310a and the counterweight elevating unit traveling frame 330a described in the third embodiment are arranged side by side, the third embodiment Unlike this, it can be used in a single-carriage type vertical conveying system that can lift only one carriage.

As such, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

100: carriage 110: carriage body
130: carriage lifting unit 150: body module
171: driving wheel module 175: guide wheel module
200: lifter 210: driving unit
220: timing belt 230: counterweight lifting unit
300: combined mast frame 310: carriage elevating unit driving frame
311: main plate 312: rail plate
330: counterweight lifting unit driving frame
350: non-contact power supply arrangement frame
400: non-contact power supply

Claims (16)

a carriage having a carriage body supporting the object to be transported, and a carriage lifting unit connected to the carriage body, the carriage being lifted between a plurality of floors;
a lifter connected to one side of the carriage elevating unit to elevate the carriage;
A carriage elevating unit traveling frame forming a carriage elevating unit traveling path through which the carriage elevating unit travels, and a counterweight elevating unit running in which a counterweight elevating unit connected to the carriage elevating unit and elevating and lowering in the vertical direction opposite to the carriage elevating unit travels a combination type mast frame in which a counterweight lifting unit traveling frame forming a passage is arranged side by side in the width direction of the carriage body; and
and a power cable connected to the carriage body,
A pair of the combined mast frames are combined with their backs facing each other to provide a cable power dual mast frame,
A vertical conveying system, characterized in that a pair of the carriage lifting and lowering units respectively travel in the pair of carriage lifting and lowering unit traveling passages of the cable power dual mast frame. According to claim 1,
The carriage elevating unit traveling frame,
and three main plates disposed adjacent to each other and surrounding the carriage elevating unit traveling path to form a traveling path of the carriage lifting unit therein;
A vertical transport system, characterized in that a coupling portion is formed on the outer wall of the main plate so as to be mutually coupled with other adjacent frames. 3. The method of claim 2,
The carriage elevating unit traveling frame,
and a pair of rail plates coupled to both free ends of the three main plates disposed adjacent to each other to contact and support the traveling wheel of the carriage elevating unit. 4. The method of claim 3,
The carriage elevating unit traveling frame,
The vertical conveying system, characterized in that the three main plates and a pair of rail plates are integrally provided by extrusion molding. 4. The method of claim 3,
The carriage elevating unit traveling frame,
A vertical conveying system, characterized in that the unit carriage elevating unit traveling frame provided by a predetermined length is stacked and coupled up and down. delete a carriage having a carriage body supporting the object to be transported, and a carriage lifting unit connected to the carriage body, the carriage being lifted between a plurality of floors;
a lifter connected to one side of the carriage elevating unit to elevate the carriage; and
A carriage elevating unit traveling frame forming a carriage elevating unit traveling path through which the carriage elevating unit travels, and a counterweight elevating unit running in which a counterweight elevating unit connected to the carriage elevating unit and elevating and lowering in the vertical direction opposite to the carriage elevating unit travels and a combination type mast frame in which a counterweight lifting unit traveling frame forming a passage is disposed side by side in the width direction of the carriage body,
The combination type mast frame,
It is disposed on one side of the carriage elevating unit traveling frame, and further comprising a non-contact power supply arrangement frame in which a non-contact power supply for supplying power to the carriage body in a non-contact manner is disposed,
The carriage elevating unit traveling frame is disposed in the center, and the counterweight elevating unit traveling frame and the non-contact power supply arrangement frame are respectively arranged on both sides of the carriage elevating unit traveling frame. 8. The method of claim 7,
A pair of the combined mast frames are coupled with their backs facing each other to provide a non-contact power dual mast frame,
A vertical conveying system, characterized in that a pair of the carriage lifting and lowering units respectively travel in the traveling passage of the pair of carriage lifting units of the non-contact power dual mast frame. According to claim 1,
The carriage body is
a carriage support frame coupled to the carriage lifting unit; and
and a horizontal transfer unit coupled to the carriage support frame to transfer the object to be transported in a horizontal direction. 10. The method of claim 9,
The carriage body is
A pair of carriage support frames further comprising a carriage body frame coupled to each other spaced apart in the vertical direction,
The carriage lifting unit is a vertical transfer system, characterized in that coupled to the carriage body frame. a carriage having a carriage body supporting the object to be transported, and a carriage lifting unit connected to the carriage body, the carriage being lifted between a plurality of floors;
a lifter connected to one side of the carriage elevating unit to elevate the carriage; and
A carriage elevating unit traveling frame forming a carriage elevating unit traveling path through which the carriage elevating unit travels, and a counterweight elevating unit running in which a counterweight elevating unit connected to the carriage elevating unit and elevating and lowering in the vertical direction opposite to the carriage elevating unit travels and a combination type mast frame in which a counterweight lifting unit traveling frame forming a passage is disposed side by side in the width direction of the carriage body,
The carriage lifting unit,
a body module disposed in the carriage elevating unit traveling passage; and
Doedoe coupled to the main body module, including at least one wheel module for guiding the elevating in contact with the elevating unit traveling frame,
The at least one wheel module is coupled to the main body module in the carriage body direction so that the at least one wheel module can be taken out of the carriage elevating unit traveling path without taking the main body module out of the carriage elevating unit traveling path. A vertical transport system, characterized in that it is detachably coupled. 12. The method of claim 11,
The at least one wheel module comprises:
a traveling wheel module having at least one traveling wheel in contact with an inner wall of the combined mast frame and traveling along the combined mast frame; and
and a guide wheel module having at least one guide wheel for guiding the lifting and lowering of the carriage lifting unit by contacting the inner wall of the combined mast frame in a direction crossing the inner wall with which the driving wheel is in contact. system. 13. The method of claim 12,
The main body module,
a driving wheel module coupling part to which the driving wheel module is slidably coupled to the carriage body; and
and a guide wheel module coupling part provided at one side of the driving wheel module coupling part and slidingly coupled to the guide wheel module in the direction of the carriage body,
A vertical transport system, characterized in that the driving wheel module coupling portion is provided with a guide adapter for guiding the sliding coupling of the driving wheel module. 14. The method of claim 13,
The traveling wheel module coupling portion has a U-shape in which a concave portion is formed toward the carriage body,
The driving wheel module,
a traveling wheel support block coupled to the concave portion; and
The vertical conveyance system, characterized in that it comprises a traveling wheel coupled to the traveling wheel support block to be rotatably relative. 15. The method of claim 14,
The driving wheel module,
and a first driving wheel module and a second driving wheel module respectively coupled to and separated from the driving wheel module coupling unit. 16. The method of claim 15,
The guide wheel module coupling part is coupled to the upper part of the driving wheel module coupling part,
The guide wheel module,
a U-shaped guide wheel support block coupled while surrounding the guide wheel module coupling part; and
and at least one guide wheel coupled to the guide wheel support block to be relatively rotatable.

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