KR20130021484A - Apparatus for guiding driving water of the gear assembly in the up-down conveyor - Google Patents

Abstract

PURPOSE: An apparatus for guiding water for driving a gear assembly of an up-down conveyor is provided to prevent the damage or malfunction of the gear assembly by preventing the inflow of driving water overflowing from an accommodation space into a driving part. CONSTITUTION: An apparatus for guiding water for driving a gear assembly of an up-down conveyor(100) comprises driving water gathers(110), driving water guide pipes(130), and guide rails(150). The driving water gathers are attached on the bottom of frames(10) which are arranged in the gear assembly of the up-down conveyor in order to collect driving water. The frames have an accommodation space(11) for placing and accommodating the gear assembly. The driving water gathers have a discharge hole to communicate with the accommodation space. One end of the driving water guide pipes is rotatably coupled to the driving water gathers, and a roller is formed on the other end thereof. The driving water guide pipes freely drop the driving water collected in the driving water gathers in order to make the driving water flow downward. The guide rails guide the movement of the roller of the driving water guide pipes.

Description

Apparatus for guiding driving water of the gear assembly in the up­down conveyor}

The present invention relates to a gear assembly driving water drop induction apparatus of an up-down conveyor, and more particularly, to an accommodation space containing a driving water for accommodating the gear assembly and provided to improve the cooling, particle removal and lubrication performance of the gear assembly. By driving the drive water from the bottom of the frame to the floor, the drive water provided to cool the heat generated in the gear assembly provided in the up-down conveyor, remove particles and increase the lubricity to prevent the falling down to overflow To prevent the surrounding contamination caused by the drive water fragmentation due to the drive water drop, and to prevent the overflow of the drive water flowing into the drive unit for driving the gears, the drive assembly of the up-down conveyor can fall guide .

A lifting conveyor is a component that can be applied to an apparatus for processing a substrate. That is, the up-down conveyor is applied to the substrate processing apparatus when the substrate is transported in the horizontal direction through the conveyor function, and the substrate is moved up and down in the vertical direction through the up-down function.

1 shows a perspective view of an up-down conveyor that can be applied to the substrate processing apparatus.

As shown in FIG. 1, the general up-down conveyor 100 includes a pair of frames 10 facing each other and a support 20 for connecting and supporting both ends of the pair of frames 10, respectively. It is configured to include).

In addition, the up-down conveyor 100 includes a horizontal transfer part 30 to transfer the substrate 1 in a horizontal direction, wherein the horizontal transfer part 30 spans the pair of frames 10. The horizontal transfer unit 30 is mounted in a state where a plurality of the horizontal transfer units 30 are spaced apart from each other by a predetermined interval.

The horizontal transfer part 30 is disposed in a state in which a plurality of transfer bars 31 disposed in a state spanning the pair of frames 10 and a plurality of consecutively spaced in the longitudinal direction of the transfer bar 31 are spaced at predetermined intervals. It comprises a feed roller 33.

As shown in FIG. 1, the frame 10 on which the transfer bar 31 is mounted is formed as a rectangular cylindrical shape extending in both sides and a bottom surface to form an accommodation space 11. In addition, the transfer bar mounting grooves 13 are formed to be spaced apart at predetermined intervals from the upper sides of the transfer bars 31.

On the other hand, both ends of the transfer bar 31 is disposed so as to be seated in the transfer bar mounting groove 13 to extend to the receiving space (11). The first gear 35 is mounted at the end of the transfer bar 31. That is, the first gear 35 connected to the end of the transfer bar 31 is disposed to be located inside the receiving space 11 of the frame 10. Although the first gear 35 in FIG. 1 illustrates a gear, all other gear shapes may be applied.

In addition, the power transmission unit 40 is disposed in the accommodation space 11 of the frame 10 in the longitudinal direction below the first gear 35. The power transmission unit 40 is disposed long in the accommodation space 11, the rotary bar 43 is rotated by the power generating unit 41 disposed on one side of the frame 10, and the rotary bar 43 It is arranged to be spaced apart at a predetermined interval, and comprises a plurality of second gears 45 are arranged to engage the first gear 35, respectively. Although the second gear 45 in FIG. 1 illustrates the gear, all other gear shapes may be applied.

As above, the first gear 35 and the second gear 45 are engaged in engagement with each other, and their coupling assemblies are referred to as gear assemblies.

In the coupling structure as described above, when the rotation bar 43 is rotated by the power generating unit 41, all of the second gear 45 is rotated in the same direction. Then, a rotational force is transmitted to the first gear 35 engaged with the second gear 45, and as a result, the transfer bar 31 is rotated, and the transfer roller formed on the transfer bar 31 ( 33) are all rotated.

Therefore, the substrate 1 mounted on one side of the horizontal transfer part 30 may be transferred in the horizontal direction on the transfer roller 33 according to the rotation of the transfer bar 31. When the front surface of the substrate 1 is seated on the feed roller 33, the driving of the horizontal transfer unit 30 is stopped.

The first gear 35 and the second gear 45 constituting the gear assembly mesh with each other so that the rotation axis of the rotation bar 43 and the rotation axis of the transfer bar 31 may be perpendicular to each other.

In the above structure, the first gear 35 and the second gear 45 constituting the gear assembly is a continuous rotation coupling during the operation of the horizontal transfer unit 30, generates heat and generates particles. And the lubricity becomes less and less.

As described above, driving water is supplied to the gear assembly to cool the heat generated in the gear assembly, to wash out the particles, and to enhance lubricity.

The drive water is provided by a drive water supply unit (not shown) disposed above or to the side of the frame 10. That is, the drive water supply unit sprays or flows the drive water to the gear assembly, thereby removing heat and particles generated from the gear assembly.

As described above, when the driving water is continuously flowed into the gear assembly, the accommodation water 11 of the frame is filled with the driving water, and the amount thereof is gradually increased to overflow from the accommodation space 11 of the frame 10. Will flow.

Then, the driving water overflowing from the accommodation space 11 causes a problem that the above-described power generation unit 41 (motor assembly) flows into the power generating unit 41, and eventually causes damage and malfunction of the power transmission unit 40, resulting in up-down. A problem arises that makes the overall operation of the conveyor 100 impossible.

In addition, the drive water overflowing from the accommodation space 11 freely falls downward to generate debris, thereby causing a problem of causing a contamination state around.

The present invention was devised to solve the above-mentioned problems of the prior art, and has a receiving space containing a driving water provided to receive a gear assembly and to improve cooling, particle removal, and lubricity of the gear assembly. By inducing the drive water to flow from the lower side of the frame to the floor, the drive water provided to cool the heat generated in the gear assembly provided in the up-down conveyor, remove particles, and improve the lubricity to prevent falling down Induces a drop in driving gear assembly of the up-down conveyor to prevent surrounding contamination caused by fragmentation of the driving water due to the driving water drop, and to prevent the overflow of driving water from the accommodation space into the driving unit for driving the gear. Providing device And to that purpose.

In order to solve the above problems, the constituent means of the gear assembly driving water drop induction apparatus of the updown conveyor, which is the present invention proposed to collect and accommodate the drive assembly provided to the gear assembly of the updown conveyor, seating and receiving The drive water is formed attached to the lower side of the frame having a receiving space, having a discharge hole so as to communicate with the receiving space, one end rotatably coupled to the drive water gutter, the drive water collected in the drive water gutter It guides so that it can flow downward by free-falling, and the other end is configured to include a guide water guide pipe for guiding the movement of the roller of the drive water guide pipe, the roller is formed, the up-down conveyor The driving water guide pipe is inclined while sliding along the guide rail It is characterized by being changed.

Here, the drive water gutter is attached to the lower side of the frame, the drive water collecting unit extending in the horizontal direction from the frame side to receive the drive water flowing from the receiving space through the discharge hole; It is attached to the lower surface of the drive water collecting unit is formed, characterized in that it comprises a drive water dropping portion to guide the drive water to the lower side and the rotational coupling with one end of the drive water induction pipe.

Here, the drive water gutter is attached to the lower surface of the frame, the drive water falling through the discharge hole to the lower side and includes a drive water falling portion that is rotated and coupled to one end of the drive water induction pipe It is characterized in that the configuration.

Here, the drive water induction pipe rotatably coupled to the drive water dropping portion is rotatably coupled to both side surfaces while receiving the drive water dropping portion, and guides the drive water falling from the drive water dropping portion downward. Rotational coupling portion is formed for the induction hole, one end is in communication with the induction hole of the rotary coupling portion and the other end is a pipe shape of the open state, the guide portion for inducing the flow of the driving water guided through the induction hole downward Characterized in that it comprises a.

Here, the counter-drive water induction pipe is further coupled to be rotatable to the counter-drive water gutter attached to the lower side of the counter frame disposed facing the frame, the counter-drive water induction pipe is disposed adjacent to the guide rail in parallel It is formed so as to slide along the opposite guide rail, the drive water induction pipe and the opposite drive water induction pipe is characterized in that adjacent to each other in the form of an X-shape.

According to the gear assembly driving water drop induction apparatus of the up-down conveyor of this invention which has the above subjects and a solution, the accommodation which accommodates a gear assembly and locks the drive water (drive water) provided for cooling the gear assembly is accommodated. Since the drive water flows from the bottom of the frame having the space to the floor, the drive water (drive number) provided to cool the heat generated by the gear assembly provided in the up-down conveyor and remove the particles overflows downward. It is effective to prevent falling, and to prevent surrounding contamination by the drive water fragments generated by the drive water drop.

In addition, there is an advantage that can prevent the overflow of the driving water in the accommodation space to the drive unit for driving the gear to prevent damage or malfunction of the gear drive unit.

1 is a block diagram of a general up-down conveyor.
2 is a perspective view of the gear assembly driving water drop induction apparatus of the up-down conveyor according to an embodiment of the present invention coupled to the up-down conveyor.
3 is a detailed view of the drive water gutter constituting the gear assembly drive water drop induction apparatus of the up-down conveyor according to the present invention.
Figure 4 is a detailed view of the drive water guide pipe constituting the gear assembly drive water drop induction apparatus of the up-down conveyor according to the present invention.
5 is an exemplary view for explaining the operation of the gear assembly driving water drop induction apparatus of the up-down conveyor according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the gear assembly driving water drop induction apparatus of the up-down conveyor of the present invention having the above problems, solving means and effects.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

Figure 2 shows a perspective view of the gear assembly drive water drop induction apparatus of the up-down conveyor according to an embodiment of the present invention coupled to the up-down conveyor.

Here, the gear assembly driving water refers to the number of operations provided to cool the heat generated in the gear assembly, remove particles and improve the lubricity, and the drop induction device is a device for guiding and directing the driving water downward it means.

As shown in FIG. 2, the gear assembly driving water drop induction apparatus of the up-down conveyor according to the present invention includes a driving water gutter 110, a driving water guide tube 130, and a guide rail 150.

The driving water gutter 110 is attached to a lower side of the frame 10 having the accommodation space 11 for receiving and receiving a gear assembly composed of a combination of the first gear 35 and the second gear 45. Is formed.

The driving water gutter 110 is attached to the lower side of the frame, and specifically, may be attached to the lower surface of the frame or attached to the lower side of the frame. The reason why the driving water gutter 110 is formed below the frame 10 is to collect the driving water filled in the accommodation space 11 of the frame 10 usefully.

The driving water gutter 110 is filled in the accommodation space 11 of the frame 10, and collects driving water for cooling the gear assembly of the up-down conveyor 100. Specifically, the driving water gutter 110 is sprayed to cool the gear assembly and collects the driving water filled in the receiving space 11 of the frame 10.

The drive water gutter 110 includes a discharge hole 111 formed to communicate with the accommodation space 11, as shown in FIG. 3, to collect the drive water filled in the accommodation space 11. do. Accordingly, the driving water filled in the accommodation space 11 is collected by being introduced into the driving water gutter 110 through the discharge hole 111.

As described above, the driving number gutter 110 may be attached to the lower side of the frame 10 (shown in FIG. 2) or may be attached to the bottom surface of the frame 10.

When the driving water gutter 110 is attached to the lower side of the frame 10, the driving water gutter 110 is formed to be in communication with the accommodation space 11, as shown in FIG. 3. A driving water dropping part attached to a lower surface of the driving water collecting unit 113 and the driving water collecting unit 113 to receive the driving water flowing from the accommodation space 11 through the discharge hole 111. And 115.

As shown in FIGS. 2 and 3, the driving water collecting unit 113 extends in a horizontal direction from the side of the frame 10. Therefore, the driving water filled in the accommodation space 11 may be introduced into the driving water collecting unit 113 through the discharge hole 111 by the hydraulic pressure.

The drive water collection unit 113 is a structure that can communicate with the accommodation space 11 through the discharge hole 111 and to form a space that can accommodate the drive water flowing from the accommodation space 11 Can be configured in various ways. For example, as shown in Figures 2 and 3, may be configured in the shape of a rectangular parallelepiped, it may be configured so that the cylindrical or cross-section is a variety of polygonal shape.

The driving water dropping unit 115 is formed on the lower surface of the driving water collecting unit 113, and the driving water dropping unit 115 moves the driving water collected by the driving water collecting unit 113 downward. Induce. Accordingly, the driving water dropping unit 115 communicates with the internal space of the driving water collecting unit 113 and has a vertical hole 115a for flowing the driving water downward.

In addition, the driving water dropping unit 115 is rotatably coupled with one end of the driving water induction pipe 130 which receives the driving water flowing downward through the vertical hole 115a and guides it to the bottom or the ground.

The reason why the driving water dropping unit 115 of the driving water gutter 110 and the driving water induction pipe 130 are rotatably coupled will be described later. When the up-down conveyor is raised or lowered, the driving water induction pipe This is to allow 130 to slide along the guide rail 150.

In detail, as the up-down conveyor 100 moves up and down, the driving water induction pipe 130 is slid along the guide rail 150 and the slope thereof is changed, which is the driving water fall of the driving water gutter 110. The unit 115 and the driving water induction pipe 130 may be rotatably coupled to each other.

Meanwhile, as described above, the driving number gutter 110 may be attached to the bottom surface of the frame 10. That is, it may be attached to the lower surface of the frame 10, not the lower side of the frame 10. In this case, unlike the driving water gutter 110 formed below the side surface of the frame 10, the driving water collecting unit is unnecessary and only the driving water dropping unit 115 is required.

Specifically, when the driving water gutter 110 is formed on the lower surface of the frame 10, the driving water gutter 110 is connected to the discharge hole 111 formed to communicate with the receiving space (11). It is configured to include a drive water drop unit 115 is guided to the driving water falling from the receiving space 11 through the lower side and the rotational coupling with one end of the drive water induction pipe 130.

Therefore, in this case, the driving water filled in the accommodation space 11 flows directly into the driving water dropping portion 115 formed to be connected to the lower surface of the frame 10, and the driving water flows into the driving water. It is guided to the ground or the bottom through the driving water guide tube 130 is rotatably coupled with the drop 115.

As described above, the driving water collected in the driving water gutter 110 is led downward (bottom or ground) through the driving water induction pipe 130. Specifically, one end of the driving water induction pipe 130 is rotatably coupled to the driving water gutter 110, and guides the driving water collected in the driving water gutter 110 to freely fall to flow downward. do.

One end of the driving water induction pipe 130 is rotatably coupled to the driving water gutter 110, and as the up and down conveyor moves up and down, the inclination of the driving water induction pipe 130 is changed while sliding on the ground. In this process, the driving water is guided to the ground. Therefore, one end of the drive water guide pipe 130 is always in a higher position than the other end.

The other end of the driving water guide pipe 130 slides along the guide rail 150 as the up and down conveyor moves up and down. Therefore, the other end of the drive water guide tube 130, as shown in Figure 4, the roller 135 is provided.

The drive water induction pipe 130 is rotatably coupled to the drive water dropping portion 115 of the drive water gutter 110, the specific configuration thereof, as shown in Figure 4, the rotary coupling portion 131, The guide part 133 and the roller 135 are comprised.

As shown in FIG. 4, the rotation coupling unit 131 is rotatably coupled to both sides in a state in which the driving water drop unit 115 is accommodated. For example, the rotation coupling unit 131 is rotatably coupled to both side surfaces of the driving water drop unit 115 through hinge coupling or pivot coupling.

The rotation coupling part 131 may be variously configured as long as the rotation coupling part 131 is rotatably coupled with the driving water dropping part 115 and prevents the driving water falling from the driving water dropping part 115 from flowing out. . For example, as shown in FIG. 4, the rotation coupling part 131 may be rotatably coupled to the driving water dropping part 115 while the upper side surface is opened. It may be a structure that is rotatably coupled to the driving water dropping portion 115 in a closed shape.

However, as shown in FIG. 4, the rotation coupling part 131 has an induction hole 131a for guiding the driving water falling from the driving water dropping part 115 downward. The guide hole 131a corresponds to the inlet of the guide part 133 which will be described later.

The guide part 133 is coupled so that one end is in communication with the induction hole 131a of the rotation coupling part 131, and the other end thereof is configured to be open. That is, one end and the other end has a pipe shape open.

The pipe-shaped guide part 133 guides the driving water guided through the induction hole 131a to flow downward. In this way, the driving water guided downward is discharged to the ground or the bottom through the other end is open.

The other end of the pipe-shaped guide portion 133 is in an open state, and the roller 135 is attached. Therefore, the driving water discharged to the outside through the other end of the guide portion 133 may be provided to the roller 135 or the guide rail 150 for guiding the roller 135, but the driving water is usually Since it is a liquid such as water, it does not adversely affect the roller or the guide rail.

The roller 135 is rolled in a guided state by the guide rail 150 described above. That is, the guide rail 150 guides the movement of the roller formed at the other end of the drive water guide pipe.

As described above, one end of the drive water induction pipe 130 is rotatably coupled to the drive water gutter 110, the other end of the drive water induction pipe 130 is provided with the roller 135 Since the guide rail 150 can be rolled in a guided state, as the up-down conveyor 100 moves up and down, the driving water induction pipe 130 is inclined while sliding (moving) along the guide rail. Is changed.

The above-described gear assembly driving water drop induction apparatus of the inventors of the up-down conveyor may be connected to only one frame 10 of the up-down conveyor, but in some cases, it is connected to both frames of the up-down conveyor. It can also be configured as.

Specifically, as shown in FIG. 2 and FIG. 5, an opposite frame disposed opposite to one frame 10 to which the driving number gatter 110 is attached among the pair of frames 10 facing each other ( A pair of driving water induction apparatus is further formed by attaching and forming the opposite driving water gutter 110 to the lower side of 10) and further coupling the opposite driving water induction pipe 130 to be rotatable to the opposite driving water gutter 110. Can be configured.

At this time, two guide rails 150 are formed such that the driving water induction pipe 130 and the opposite driving water induction pipe 130 may slide. That is, the opposite drive water guide tube 130 is formed to slide along the opposite guide rail 150 disposed in parallel with the guide rail 150, the drive water guide pipe 130 and the opposite drive The male guide tube 130 is disposed adjacent to each other in an X shape.

In summary, the counter-drive water guide tube 130 is further coupled to the counter-drive water gator 110 attached to the lower side of the counter frame 10 disposed to face the frame 10, and the counter-drive. The water induction pipe 130 is formed to slide along the opposite guide rail 150 disposed in parallel with the guide rail 150, and the driving water induction pipe 130 and the opposite driving water induction pipe 130 ) Are arranged adjacent to each other in an X-shape to form a gear assembly driving water drop induction apparatus of a pair of up-down conveyors.

5 is an exemplary view for explaining the operation of the gear assembly driving water drop induction apparatus of the up-down conveyor described above.

As shown in FIG. 5, as the up-down conveyor 100 moves up and down, the other end of the driving water guide pipe 130 slides along the guide rail 150, and its slope is changed. In this process, since one end of the driving water induction pipe 130 is always present at a higher position than the other end, the driving water may be led to the ground (the side with the roller) along the driving water induction pipe.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

1: board 10: frame
11: accommodation space 13: transfer bar mounting groove
20: support 30: horizontal feed
31: transfer bar 33: transfer roller
35: first gear 40: power transmission unit
41: power generating unit 43: rotary bar
45: second gear 100: up-down conveyor
110: driving water gator 111: discharge hole
113: drive water collection unit 115: drive water dropping portion
115a: vertical hole 130: drive water induction pipe
131: rotation coupling portion 131a: induction hole
133: guide 135: roller
150: guide rail

Claims (5)

A drive water gutter attached to a lower side of a frame having a receiving space for receiving and receiving the gear assembly, for collecting drive water provided to a gear assembly of an up-down conveyor, and having a discharge hole to communicate with the receiving space;
A driving water induction pipe having one end rotatably coupled to the driving water gutter, freely dropping the driving water collected in the driving water gutter, so as to flow downward, and a roller formed at the other end;
It is configured to include a guide rail for guiding the movement of the roller of the drive water guide pipe,
As the up and down conveyor is moved up and down the drive water induction pipe is sliding along the guide rail while the slope of the gear assembly drive water fall induction apparatus of the up and down conveyor characterized in that the change.
The method according to claim 1,
The drive water gutter is attached to the lower side of the frame, the drive water collecting unit extending in the horizontal direction from the side of the frame to receive the drive water flowing from the receiving space through the discharge hole, and the drive It is attached to the lower surface of the water collecting unit is configured to include a drive water drop unit for driving the drive water to the lower side and is coupled to one end of the drive water induction pipe rotation drive assembly of the up and down conveyor characterized in that it is configured.
The method according to claim 1,
The driving water gator is attached to the lower surface of the frame, and includes a driving water drop unit which guides the driving water falling from the receiving space through the discharge hole to the lower side and is rotatably coupled with one end of the driving water induction pipe. Gear assembly drive water drop induction apparatus of the up-down conveyor, characterized in that.
The method according to claim 2 or 3,
The drive water induction pipe rotatably coupled to the drive water dropping portion is rotatably coupled to both sides in a state in which the drive water dropping portion is accommodated, and guides the drive water falling from the drive water dropping portion downward. Rotating coupling part is formed in the hole, the induction hole of the rotary coupling portion and one end is in communication with the pipe shape of the other end is open, including a guide for inducing the flow of the driving water guided through the guide hole downward Gear assembly drive water drop induction apparatus of the up-down conveyor, characterized in that configured.
The method of claim 4,
Opposite drive water induction pipes are further coupled to be rotatable to opposing drive gas gutters attached to the lower side of the opposing frame disposed to face the frame, and the opposing drive water induction pipes are disposed to be parallel to and adjacent to the guide rails. It is formed to slide along the guide rail, the drive water guide pipe and drive water drop induction apparatus of the gear assembly of the up-down conveyor, characterized in that the adjacent drive water guide pipe is disposed adjacent to each other in an X-shape.

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