KR102415113B1 - Vibrator drive unit - Google Patents

Abstract

The present invention relates to a vibrator used to remove air bubbles contained in mortar during pouring of concrete mortar in the process of constructing a building. This is to make it possible to pour concrete mortar while moving the power unit while carrying the power unit as well as reducing the size and weight of the power unit.
To this end, the present invention is driven according to the application of power, and a BLDC motor 100 having a first heat dissipation fin 101 formed on an outer peripheral surface thereof, and a driving gear 121 fixed to an output shaft of the BLDC motor 100 are meshed with each other. A gear housing ( The reduction gear part 120 wrapped with 123), the rotation joint 124 fixed to the shaft of the driven gear 122, rotating in a reduced state, and one end of the drive transmission cable 110 is coupled, and the rotation joint A cover 130 that surrounds 124 and is fixed to the gear housing 123, is installed to surround the BLDC motor 100, a second heat dissipation fin 141 is formed over the entire inner circumferential surface, and the outer circumferential surface is flat housing 140 and a controller 160 installed at one end of the BLDC motor 100 to turn on and off the power of the BLDC motor 100, and a first hook hole 171a fixed to the bottom surface of the controller 160 It is characterized in that the bracket 171 is composed of a control cover 170 integrally formed.

Description

Vibrator drive unit

The present invention relates to a vibrator used to remove air bubbles contained in mortar during the pouring of concrete mortar in the process of constructing a building, and more specifically, to generate power to drive the perforated vibrating rod It relates to a vibrator driving device that enables the pouring of concrete mortar while a worker moves while carrying the power unit by applying a BLDC motor to the power unit to reduce the size and weight of the power unit.

In general, a brief description of the process of constructing a building using a concrete mortar at a construction site is as follows.

First, in order to maintain sufficient strength according to the pouring of the concrete mortar, several strands of reinforcing bars are appropriately placed on the pouring part of the concrete mortar, tied with a thin wire, and then the form is wrapped around the outside and installed.

In this way, when the formwork installation work is completed, the concrete mortar in which cement, sand, and gravel in an appropriate ratio are mixed with water and evenly mixed is transported by a ready-mixed concrete vehicle, and the concrete mortar pouring work is performed.

As described above, after pouring the concrete mortar through the formwork, and then passing through a curing process for a certain period of time, the formwork is removed to complete the structure of the building.

However, before the concrete mortar transported by the ready-mixed concrete vehicle is put between the formwork during the pouring operation of the above-mentioned concrete mortar, innumerable fine air bubbles exist in the concrete mortar. As it remains, the strength of concrete is significantly lowered, and there is a risk of collapsing accidents.

Therefore, when pouring concrete mortar, air bubbles must be removed, and the equipment used at this time is a vibrator.

The vibrator serves to remove air bubbles present in the concrete mortar by allowing rapid vibration to be applied to the concrete mortar during the pouring operation of the concrete mortar.

1 is a perspective view showing an embodiment of a conventional vibrator, a vibrating rod 1 that applies vibration to the concrete mortar during the concrete mortar pouring operation, and a vibration rod with power generated by being connected to the vibrating rod by a hose 2 It consists of a power unit (3) that rotates a rotary shaft built into (1) to generate vibration.

2 is a longitudinal cross-sectional view showing a conventional perforated vibrating rod, the housing 5 made of a cylindrical unitary body is connected to the end of the hose 2 having a flexible cable 4 embedded therein, and the interior of the housing A rotary shaft 6 is installed to be supported by a bearing 7 and one end is connected and fixed to the flexible cable 4, and the other end of the rotary shaft 6 is a head cap screwed to the end of the housing 5. It is located in the form of a free end inside of (8).

Therefore, when the vibration rod (1) is put inside the concrete mortar and then the power unit (3) is operated during the concrete mortar pouring operation, the flexible cable (4) built into the hose (2) is rotated by the generated power. The rotary shaft 6 fixed to the end of the flexible cable 4 rotates.

At this time, one end of the rotary shaft 6 is supported by the bearing 7 , and the end is located inside the head cap 8 in a free end state, so that the rotary shaft is located inside the head cap 8 . The end of (6) collides with the inside of the head cap 8 to induce vibration, and the generated vibration removes air bubbles contained in the concrete mortar.

Republic of Korea Patent Publication No. 10-0782997 (2007.12.06. Announcement) Republic of Korea Patent Publication No. 10-1631559 (2016.06.17. Announcement) Republic of Korea Registered Utility Model Publication No. 20-0169437 (2000.02.15. Announcement) Republic of Korea Registered Utility Model Publication No. 20-0473088 (2014.06.10.Announcement)

However, as an AC motor weighing about 20 kg is applied as the power unit of this conventional vibrator, it is heavy, so it takes a lot of effort to move the power unit quickly depending on the location of the concrete mortar, and it is also difficult to transport and store. there was

The present invention has been devised to solve the problem of the prior art, and as the BLDC motor is applied to the power generating unit, the number of revolutions is reduced by a reduction gear and output, and generated according to the driving of the BLDC motor. The purpose is to reduce the size and weight of the power unit by enclosing the BLDC motor by a housing with heat dissipation fins formed therein.

Another object of the present invention is to flatten the outer surface of the housing and to rapidly dissipate the high heat generated by the operation of the BLDC motor to the outside, so that the phenomenon of contamination of the housing by concrete mortar, etc. even in a poor environment can be fundamentally solved. is to do

Another object of the present invention is to enable a worker to carry a power unit or to enable a concrete mortar pouring operation while moving while being hung on an iron beam, thereby reducing the number of working people.

According to the aspect of the present invention for achieving the above object, it is driven according to the application of power and is meshed with a BLDC motor having a first heat dissipation fin formed on its outer circumferential surface, and a driving gear fixed to an output shaft of the BLDC motor) to engage the output shaft of the BLDC motor. It consists of a driven gear that reduces the number of revolutions from 10,000 to 15,000 rpm to 3,500 to 5,000 rpm, and a reduction gear part wrapped with a gear housing provided with an extra tooth having a second hook hole, and the speed is fixed to the shaft of the driven gear and reduced A rotating joint to which one end of the drive transmission cable is coupled while rotating with a rotator, a cover fixed to the gear housing while surrounding the rotating joint, and a housing that is installed to surround the BLDC motor and has a second heat dissipation fin formed over the entire inner circumferential surface and has a flat outer circumferential surface And, a controller installed at one end of the BLDC motor to turn on and off the power of the BLDC motor, and a control cover fixed to the bottom of the controller and having a bracket having a first hook hole formed integrally with the vibrator driving device is provided

The present invention has the following advantages over the prior art.

First, the drive transmission cable is rotated while the rotation speed of the small and light BLDC motor is reduced to operate the vibrator's perforated vibrating rod. This makes it possible to perform concrete mortar work even with a reduction in the number of workers.

Second, the first and second heat dissipation fins are formed on the BLDC motor and the housing, respectively, and the cooling fan is rotatably installed at the rear of the BLDC motor to prevent overheating of the BLDC motor and extend the life of the BLDC motor. However, since the outer surface of the housing is flattened, it is possible to fundamentally solve the phenomenon of contamination of the housing by concrete mortar, etc. even in a harsh environment.

Third, since the first and second hanging holes are formed in the controller and gear housing, it is possible to carry out the concrete mortar pouring operation while the operator hangs the power part on a steel beam, etc. without carrying the power unit.

1 is a perspective view showing an embodiment of a conventional vibrator
2 is a longitudinal cross-sectional view showing a conventional perforated vibrating rod;
3 is an exploded perspective view showing the configuration of the present invention;
Figure 4 is a perspective view of the combined state of Figure 3;
5 is a longitudinal cross-sectional view of FIG.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. The present invention may be implemented in several different forms and is not limited to the embodiments described herein. It is noted that the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and not limiting. And the same reference numerals are used to denote like features to the same structure, element, or part appearing in two or more drawings.

3 is an exploded perspective view showing the configuration of the present invention, FIG. 4 is a perspective view of the combined state of FIG. 3, and FIG. 5 is a longitudinal cross-sectional view of FIG. A first heat dissipation fin 101 is formed over the entire outer circumferential surface.

The BLDC motor 100 has a size of Φ45 ~ 60mm, a length of about 100 ~ 130mm, an output of 0.5 ~ 2Kw, and an rpm of 10,000 ~ 15,000, which is reduced to 3500 ~ 5000rpm by a reduction gear and a drive transmission table (110) Because it rotates the device of the present invention can be made compact (compact).

However, it is understandable that the BLDC motor 100 can be applied by changing it into various shapes, such as a square or a rectangle, as shown in FIG. 3 shown as an embodiment.

A driving gear 121 is fixed to the output shaft of the BLDC motor 100 as shown in FIG. 5, and a driven gear 122 for decelerating the output shaft rotation speed of the BLDC motor 100 is meshed with the driving gear 121. The driving gear 121 and the driven gear 122 are surrounded by the gear housing 123 to constitute the reduction gear unit 120 .

At this time, a rotation joint 124 to which one end of the drive transmission cable 110 is coupled is fixed to the shaft of the driven gear 122, and as the BLDC motor 100 is driven, the rotation joint ( 124 is rotated in a decelerated state, the rotary joint 124 is wrapped in a cover 130 , and the cover 130 has an insertion hole 111a of the adapter 111 installed at one end of the drive transmission cable 110 . ), a fixed key 131 fitted and fixed is elastically installed with a spring (not shown) so as to be retractable, and the cover 130 is fixed to the gear housing 123 .

The BLDC motor 100 is protected by being wrapped around the housing 140 in which the second heat dissipation fin 141 is formed over the entire inner circumferential surface. The reason for forming the mortar is to fundamentally prevent a phenomenon in which the space between the second heat dissipation fins 141 is filled with the concrete mortar and cured even if the concrete mortar is bounced and buried in the housing 140 in the working environment of pouring the concrete mortar.

If the second heat dissipation fins 141 are formed outside the housing 140 and the space between the second heat dissipation fins 141 is filled with concrete mortar and cured, the heat dissipation effect of the BLDC motor 100 is lost.

In addition, a cooling fan 150 for cooling the heat generated according to the driving of the BLDC motor 100 is rotatably installed at the rear of the BLDC motor 100 .

The cooling fan 150 may be of a type that rotates by itself as power is applied, or may be designed to rotate by driving the BLDC motor 100 , so there is no need to limit the cooling fan 150 .

A controller 160 for turning on and off the power of the BLDC motor 100 is installed at one end of the housing 140, and the recess 142 formed in the housing 140 has a BLDC motor so as not to be damaged by an external impact. A switch 161 for applying power to 100 is installed so as to be accommodated.

In this case, the switch 161 may further include an LED (not shown) so that the switch 161 can be easily identified even in a dark place.

In addition, a bracket 171 is integrally formed on the controller cover 170 fixed to the rear of the controller 160, and the bracket 171 has a power unit by means of a separate ring (not shown) by means of a steel beam ( A first hook hole 171a is formed so as to be hung on the gear housing 123 , and a second hook hole 125a is also formed on the rib 125 formed in the gear housing 123 .

The operation of the present invention will be described as follows.

First, in the device of the present invention assembled as shown in FIG. 5 , the fixing key 131 is pulled so that the spring (not shown) is compressed, and then the adapter 111 fixed to the end of the drive transmission cable 110 is rotated through the joint. When it is pushed toward the 124 side, one end (hexagonal shape) of the drive transmission cable 110 is inserted into the hexagonal groove 124a formed in the rotary joint 124, and the external force is removed from the fixed key 131 that was being pulled in this state. When the lower fixed key 131 is returned to its initial state by the restoring force of the spring, it is inserted into the insertion hole 111a formed in the adapter 111, and the drive transmission cable 110 in the cover 130 rotates while the drive transmission cable 110 rotates. ) to prevent the escape phenomenon.

After coupling the drive transmission cable 110 to the cover 130 of the present invention in this way, the perforated vibrating rod (not shown) is put into the concrete mortar, and the switch 161 installed in the recess 142 of the housing 140 ) is turned on, since power is applied to the BLDC motor 100 and the cooling fan 150 by the controller 160, the BLDC motor 100 rotates at a high speed of 10,000 to 15,000 rpm.

When the BLDC motor 100 rotates at a high speed of 10,000 to 15,000 rpm, it is decelerated to 3500 to 5000 rpm by the gear ratio of the driving gear 121 and the driven gear 122 constituting the reduction gear unit 120 to the rotation joint 124. By rotating the coupled drive transmission cable 110 to apply vibration to the perforated vibrating rod, air bubbles contained in the concrete mortar are removed.

The operation as described above is carried out by the operator because the device of the present invention is light and small in volume, or hung on an iron beam (not shown) using the first and second hanging holes (171a) and (125a) and rings. Convenience of use is provided because it is possible to carry out the pouring work of concrete mortar while moving freely.

When heat is generated inside the housing 140 as the BLDC motor 100 is driven, the generated heat is applied to the first and second heat dissipation fins 101 and 141 formed in the BLDC motor 100 and the housing 140, respectively. As the cooling fan 150 rotates and cools the heat generated while the cooling fan 150 rotates according to the application of power at the same time as the heat is radiated to the outside, the phenomenon in which the BLDC motor 100 is overheated can be fundamentally solved.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential features. will be.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention described in the above detailed description is indicated by the following claims, meaning and All changes or modifications derived from the scope and its equivalents should be construed as being included in the scope of the present invention.

100: BLDC motor 101: first heat dissipation fin
110: drive transmission cable 111: adapter
120: reduction gear unit 121: drive gear
122: driven gear 123: gear housing
124: rotary joint 130: cover
131: fixed key 140: housing
141: second heat dissipation fin 150: cooling fan
160: controller

Claims (2)

It is driven according to the application of power, and the BLDC motor 100 having a first heat dissipation fin 101 formed on the outer circumferential surface is meshed with the driving gear 121 fixed to the output shaft of the BLDC motor 100, and the BLDC motor 100 is It is composed of a driven gear 122 for decelerating the output shaft rotation speed from 10,000 to 15,000 rpm to 3,500 to 5,000 rpm, and a gear housing 123 provided with a rib 125 having a second hook hole 125a formed therein. The fisherman 120, the rotation joint 124 fixed to the shaft of the driven gear 122, rotating in a reduced state, and one end of the drive transmission cable 110 coupled thereto, and the rotation joint 124 surrounding the gear A cover 130 fixed to the housing 123, installed to surround the BLDC motor 100, a second heat dissipation fin 141 is formed over the entire inner circumferential surface, and a housing 140 having a flat outer circumferential surface, and the BLDC motor ( A controller 160 installed at one end of 100 and turning on and off the power of the BLDC motor 100, and a bracket 171 fixed to the bottom surface of the controller 160 and having a first hook hole 171a are integrated. Vibrator driving device, characterized in that consisting of a control cover 170 formed of. delete

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