KR102477852B1 - Polisher For Protecting Discharged Air And Discharged Air Shield - Google Patents

Abstract

The present invention is a case with an opening formed;
a driving unit included in the case;
a coating unit having a coating pad rotated by the driving shaft of the driving unit; and,
Through the opening, the driving heat generated by the driving unit is discharged, and a fixing unit disposed to cover the opening; and
The present invention relates to a polisher having an exhaust air shield including an exhaust air guide for discharging high-temperature exhaust air discharged through the opening in a predetermined direction when the driving unit is operated.

Description

Polisher For Protecting Discharged Air And Discharged Air Shield}

The present invention relates to a polishing machine or an exhaust air shield for automobiles having an exhaust air shield, wherein the shield prevents exhaust air discharged from the polisher from being blown directly to a worker while performing a polishing operation by applying the polishing agent to a vehicle. It relates to a polisher and a shield provided.

A vehicle is a means of transporting passengers or cargo by transmitting power generated from an engine to wheels, and has continued to make remarkable progress with the advent of self-driving cars and electric vehicles.

In this way, as automobiles are functionally developed, developments in related fields are also rapidly occurring. On the other hand, there were many changes in terms of appearance and design as well as functional parts.

As the preference for internal combustion engine vehicles has changed from means of transportation to the realm of emotional luxury goods, changes and developments in related products have also been accompanied.

Due to the nature of automobiles exposed to the external environment, the state of the exterior paint is important, and it is important to maintain it. In order to maintain the gloss of the painted surface, it is common to apply a coating material to the painted surface of the vehicle and coat the coating material on the painted surface with a specific pad to maintain the coating.

Devices for applying and coating the coating material as described above on a painted surface are available for use by individual users, and there are various types thereof.

Republic of Korea Patent Application No. 10-2010-0029758 describes a vehicle polisher, which is a well-known form that is particularly easy to carry and use. It consists of a structure in which the axis of the drive motor and the axis of rotation of the coating pad are perpendicularly crossed and driven.

U.S. Patent Application No. 09/571,828 exemplifies a mechanism in which the trajectory is deformed, and has a structure consisting of the drive shaft of the above-mentioned Korean Patent Application No. 10-2010-0029758 and the coating pad rotation shaft intersected in a direction perpendicular to the drive shaft. have a similar structure. Conventional vehicle polishers have a structure in which the rotating shaft of the coating pad is dispersed so that the momentum of the polisher is dispersed on the target surface. In order to handle this distributed rotational force, a large amount of momentum of the drive shaft must be provided, and accordingly, a relatively large amount of driving energy is required.

Meanwhile, an abrasive supply means is further provided to directly apply the polish or abrasive provided in Korean Patent Application No. 10-2010-0029758 to the target surface so that the polish or abrasive can be coated on the target surface. On the other hand, the brightening agent may be provided and coated on the target surface by a separate means. At this time, as large drive energy is provided to the polisher as described above, large thermal energy is generated during operation.

As described above, since a large driving energy is applied to the driving shaft of the polisher as described above, there is a need to remove the heat energy generated therein, and usually, for this purpose, the driving motor or the driving shaft and the coating pad rotating shaft meet and change An opening is provided at the part to be discharged.

In order to remove the heat generated when the polisher is driven, the heat is removed by an air cooling method in which air flows and cools. The heat generated by the drive motor of the polisher is taken away by the air and discharged to the outside. The high-temperature air discharged around the driving shaft of the driving motor is blown out toward the user through the opening or the like.

Thus, there is a need to change the air flow so that the hot exhaust air does not directly contact the user.

As described above, a polishing machine is used to maintain a glossy state of the painted surface of a vehicle. While the polisher is driven, there is a need to provide a polisher equipped with a means for preventing hot air from being discharged from a hot gas disposed near a drive shaft from directly contacting a user.

An object of the present invention is to provide a high-temperature exhaust air shield that can be provided in a polisher or an existing polisher to prevent such high-temperature exhaust air from directly contacting a user.

As described above, the object of the present invention is,

a case in which an opening is formed;

a driving unit included in the case;

a coating unit having a coating pad rotated by the driving shaft of the driving unit; and,

Through the opening, the driving heat generated by the driving unit is discharged, and a fixing unit disposed to cover the opening; and

An exhaust air shield including an exhaust air guide for discharging high-temperature exhaust air discharged through the opening in a predetermined direction when the drive unit is operated.

This is achieved by providing a polisher with an exhaust air shield comprising

Preferably, the exhaust air guide of the exhaust air shield includes a main exhaust air guide and an auxiliary exhaust air guide, and the main exhaust air guide is formed in a direction crossing the direction of the rotation axis of the drive unit.

Also preferably, the exhaust air guide of the exhaust air shield includes a main exhaust air guide and an auxiliary exhaust air guide, and the main exhaust air guide is formed in the same direction as the direction of the rotational axis of the drive unit.

In addition, an object of the present invention is an exhaust air shield that blocks an opening provided in a polisher,

A fixing unit disposed to cover the opening and discharging driving heat generated in the polisher through the opening; and

This is achieved by providing an exhaust air shield including an exhaust air guide that collects hot exhaust air discharged through the opening during operation of the polisher and discharges it in a certain direction.

By providing a polisher having an exhaust air shield or an exhaust air shield according to the present invention, it is possible to effectively prevent high-temperature exhaust air generated during operation of the polisher from being discharged to the operator or the surroundings during the process of applying the polish coating operation to the painted surface of the vehicle. let it be

1 is a schematic diagram illustrating a polisher of one embodiment of the present invention having an opening;
2 is a schematic diagram illustrating a polisher with an exhaust air shield according to one embodiment of the present invention.
3 is a schematic diagram illustrating an exhaust air shield according to one embodiment of the present invention.
Figure 4 is a front view illustrating the exhaust air shield illustrated in Figure 3;
5 is a front view illustrating an exhaust air shield according to another embodiment of the present invention.
Figure 6 is a front view illustrating that the auxiliary exhaust air guide of the exhaust air shield of the present invention is disposed in the same direction as the rotational axis of the drive unit.
Figure 7 is a schematic diagram illustrating that the inner contact interface of the exhaust air shield of another embodiment of the present invention is formed as a curve.
FIG. 8 is an explanatory view illustrating air passing through the exhaust air shield of FIG. 7 and an opening formed in the case of the polisher of the present invention.

The polisher of the present invention is a vehicle polisher, and covers all polishers including portable ones.

1 is a schematic diagram illustrating a polisher of an embodiment of the present invention having an opening, and the polisher of the present invention is not limited by FIG. 1 .

Typically, the polisher includes a driving unit 200 such as a driving motor in a case 100. The case 100 is provided with a handle 120 for manipulating the polisher on one side, and the drive unit 200 is connected to the coating unit 300 having a coating pad 310, and is fastened with a gear or the like. It is applied as a conventional technology such as a system, and its description is omitted in the present invention.

In Figure 1, the rotation axis A of the driving unit 200 and the rotation axis B of the coating unit 300 are disposed in a direction crossing each other, the present invention is not limited thereto, and the rotation axis A of the driving unit 200 and the coating unit 300 A polisher in which the rotational axis B of ) is disposed in the same direction is also included in the present invention.

The driving unit 200 of the polisher is operated by providing high energy, and accordingly, a lot of heat is generated and there is a need to effectively remove it. In order to remove such thermal energy, an opening 110 is disposed on one side of the case 100 as in the present invention. The opening 110 is preferably disposed in a portion of the drive shaft (not shown for simplicity of explanation) in the downstream stream of the rotation axis A of the drive unit 200, and the opening 110 of the drive unit 200 It may be disposed around a portion where the drive shaft and the coating unit 300 are connected to each other.

When the opening 110 is disposed in the case 100, it is effective in removing heat energy generated by the operation of the polisher.

As illustrated in FIG. 2 , the polisher of the present invention includes an exhaust air shield 10 to cover the opening 110 formed in the case 100 .

As described above, the arrangement of the opening 110 is not limited, and the exhaust air shield 10 is disposed at a portion where the rotational momentum of the rotational axes A and B is large.

Figure 3 shows the discharge air shield 10 according to an embodiment of the present invention, a fixing part 5 for fixing to the case 100 of the polisher and a spacer 6 installed around the fixing part 5, It consists of a shield frame (20). The exhaust air shield 10 is fixed to the case 100 by the fixing part 5 and the fixing part 15 . These are fixed to each other in a manner such as a screw type, an insert type, an adhesive type, etc., and there is no limitation thereto.

The exhaust air shield 10 is not limited as long as it is a material capable of forming a three-dimensional shape, and preferably synthetic resins, PE, PP, PS, ABS, PET, PBT, PVC, PC, BMC, and silicone. There is no limit to the resin and the like.

The shield frame 20 is formed in a structure to cover the opening 110 formed in the case 100, and has a main discharge air guide 1 and a secondary scattering guide 2. The main exhaust air guide 1 varies according to the arrangement position of the opening 110 of the case 100.

As illustrated in FIG. 3 , it is preferable that the main exhaust air guide 1 be disposed perpendicular to or substantially perpendicular to the rotation axis A when disposed on the drive shaft side of the rotation axis A of the driving unit 200 .

In this embodiment, one side of the shield frame 20 on which the main exhaust air guide 1 is formed is open and the other side has a blocking portion 21 so that exhaust air loaded with maximum rotational momentum passes through the opening 110. This will prevent it from spraying out directly to the outside of the polisher.

As the air flow is blocked by the blocking portion 21 of the shield frame 20, the air flow is blocked. At this time, an auxiliary exhaust air guide 2 is formed on the end shield frame 20' for air flow. According to this configuration, the discharge air passing through the opening 110 passes through the main exhaust air guide 1 and the flow direction is changed at the blocking part 21 or the auxiliary exhaust air guide without touching the blocking part 21. (2) is discharged.

Preferably, the auxiliary exhaust air guide 2 is inclined obliquely with respect to the rotational axis A of the driving unit 200 . As the auxiliary exhaust air guides 2 are disposed in succession in the downstream stream of the main exhaust air guide 1, the exhaust air discharge rate is improved.

When the auxiliary exhaust air guide 2 is not installed, since the exhaust air generated by the rotational momentum is reduced, the heat exhaust is not smooth, so a large heat load is formed on the drive unit 200 of the polisher, and the temperature rises. do.

As the main exhaust air guide 1 and the auxiliary exhaust air guide 2 are provided, exhaust air is effectively discharged and heat energy is effectively discharged.

The exhaust air shield 10 is fixed to the polisher case 100 by a fixing part 5 provided on one side of the exhaust air shield 10 . At this time, it is disposed in the protruding spaced part 6 around the fixing part 5, and the discharge air shield 10 and the case 100 are spaced apart by the spaced part 6. , Air flow is smoothly accompanied through the spacers 6 to help dissipate heat energy.

5 is a front view illustrating an exhaust air shield according to another embodiment of the present invention.

As illustrated in FIG. 5, only the main exhaust air guide 1 is disposed without the auxiliary exhaust air guide 2 and the blocking portion 21 on the shield frame 20 of the exhaust air shield 10 of the present invention. As an example, this can be applied in a working environment in which less exhaust air is generated or when using a polisher, and allows the polisher to discharge heat smoothly.

6 is a front view illustrating that the auxiliary exhaust air guide 3 of the present invention is disposed in the same direction as the driving shaft of the driving unit 200. Referring to FIG.

The arrangement of the main exhaust air guide 1 formed on the shield frame 20 of the exhaust air shield 10 of FIG. 6 is similar to FIGS. 3 and 4, but the arrangement of the auxiliary exhaust air guide 3 is different. This structure is a structure for increasing the discharge of thermal energy by making the air flow more smoothly by the rotational momentum of the exhaust air. The secondary discharge air guide 3 is disposed in the same direction as the rotation axis A of the driving unit 200 of the polisher.

As described above, the structure of the exhaust air shield 10 may be differently disposed according to the arrangement of the opening 110 of the polisher. As described above, when the opening is disposed around the driving shaft on the rotation axis A of the driving unit 200, the main exhaust air guide 1 and the auxiliary exhaust air guide 2, as shown in FIGS. 3, 5 and 6, 3) may have an orientation form. This orientation shape depends on the discharge direction of exhaust air generated according to the rotational momentum of the rotating shaft A of the driving unit 200 .

Although not illustrated in the drawing, when the opening 110 is disposed around the shaft conversion means such as a conversion gear on the rotation axis B of the coating unit 300, the main exhaust air guide 1 and the auxiliary air guide 1 and the secondary Exhaust air guides 2 and 3 may be arranged in an intersecting direction. This is to be arranged in the same orientation with respect to the axis of rotation A.

As illustrated in FIG. 7 , in another embodiment of the present invention, the inner contact interface of the exhaust air shield may be curved.

The exhaust air shield 10 'as illustrated in FIG. 7 has a large imaginary interface at the inlet side so that the air flow is accelerated, and the air passes through the opening 110 and narrows, again forming a virtual interface. As it is discharged into the enlarged discharge space, the air pressure is lowered and thus, the air flow rate is increased to achieve smooth heat discharge.

The main exhaust air guide 1 and the auxiliary exhaust air guides 2 and 3 are formed on the shield frame 20 "of the exhaust air shield 10' having a curved inner contact portion F to discharge the exhaust air , and smooth air flow to perform the polishing operation of the polisher.Thereby, when the polishing agent is applied to the painted surface of a car and coated, exhaust air that can contaminate workers and surroundings can be effectively blocked.

1: Main exhaust air guide
2, 3: Auxiliary Exhaust Air Guide
5: fixed part
6: bonding interface
10, 10': exhaust air shield
15: fixture
20, 20', 20" : Exhaust air shield flame
21: blocking part
100: Polisher
110: opening
120: handle
200: driving unit
300: coating part
310: coating pad

Claims (4)

a case in which an opening is formed;
a driving unit included in the case;
a coating unit having a coating pad rotated by the driving shaft of the driving unit; and,
Through the opening, the driving heat generated by the driving unit is discharged, and a fixing unit disposed to cover the opening; and
An exhaust air shield formed with an exhaust air guide for discharging high-temperature exhaust air discharged through the opening in a predetermined direction when the drive unit is operated;
The exhaust air guide is composed of a main exhaust air guide and an auxiliary exhaust air guide,
The main exhaust air guide is formed in a direction perpendicular to the direction of the rotation axis of the drive unit,
The inner contact interface of the exhaust air shield is formed in a curved shape so that a portion of the exhaust air guide formed on the exhaust air shield becomes larger, narrows while passing through the opening, and a portion through which air is discharged becomes larger. Polishers with exhaust air shields. delete delete In the exhaust air shield formed with the exhaust air guide,
The exhaust air guide is composed of a main exhaust air guide and an auxiliary exhaust air guide,
The inner contact interface of the exhaust air shield is formed in a curved shape so that a portion of the exhaust air guide formed on the exhaust air shield becomes larger, narrows while passing through the opening, and a portion through which air is discharged becomes larger. exhaust air shield.

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