KR101197171B1 - Belt tensioner - Google Patents

Abstract

The present invention relates to a belt tensioning device for transmitting power, specifically a housing; A rotating shaft coupled to the center of the housing; A spiral spring installed in a state in which the rotating shaft is wound and fixed to both ends of the spiral spring, respectively; A rod having one end coupled to the rotation shaft; And a roller that is axially coupled to the other end of the rod, thereby providing a belt tensioning device having a wider range of tension adjustment by the spiral spring and a free installation position or angle.

Description

Belt tensioning device {Belt tensioner}

The present invention relates to a belt tensioning device formed to adjust the tension of the belt connecting the power.

In a vehicle that operates various electronic devices including a cooling device using the power of an engine, pulleys are respectively coupled to the rotating shafts of the engine, the compressor, and the generator, and each pulley is connected by a belt.

A tension control device is installed to tightly connect the pulleys using the belt.

As an example of the tension control device as shown in Figure 1 bracket (10); A housing 20 axially coupled to the bracket; A roller 30 coupled to one side of the housing and in close contact with the belt; And a coil spring 40 installed between the bracket and the housing and pushing the rod in the belt direction.

As such, the belt tension adjusting device according to the related art makes it possible to maintain the tension of the belt by making the roller closely adhere to the belt by using the elastic force of the coil spring.

The present invention is to solve the conventional problem that the belt tension control device using the coil spring is short in the range of tension adjustment because the elastic force of the coil spring is short and the straightness is limited, the installation position and angle is limited.

The present invention is to solve the conventional problem that the belt tensioning device using the coil spring is limited to the integrated device using the pulley belt because a lot of constraints occur in the range and the installation position and angle of the tension adjustment.

Belt tensioning device of the present invention is a housing; A rotating shaft coupled to the center of the housing; A spiral spring installed in a state in which the rotating shaft is wound and fixed to both ends of the spiral spring, respectively; A rod having one end coupled to the rotation shaft; And a roller axially coupled to the other end of the rod.

The housing is formed with a gutter so as to surround the outer surface in a state in which one end of the rotating shaft is coupled to the shaft, the cap portion of the gutter formed flange to cover the spiral spring; An edge portion coupled to an edge of the flange, the edge portion being cut at an angle such that the rod rotates while surrounding the sides of the rod and the spiral spring; And a panel portion coupled to the edge portion, the other end of the rotating shaft being coupled to the shaft, and configured to cover the spiral spring.

And a bearing fixedly installed in the cap of the housing and formed to surround and support the rotating shaft.

Key protrusions are formed on the rotating shaft, and key grooves are formed on the rod to be keyed to each other.

According to the belt tensioning device of the present invention by using the elastic force of the spiral spring to have a long distance and the rotational force of the elastic force, the range of the tension adjustment is further widened, there is an effect that the installation position or angle is free.

According to the belt tensioning device of the present invention, the range of the tension adjustment is widened and is not restricted by the installation position or angle, thereby having the effect of being applicable to all belts.

1 is a front view showing an embodiment of a conventional belt tensioning device.
Figure 2 is a perspective view showing a belt tensioning device to which the present invention is applied.
Figure 3 is a cross-sectional view showing a belt tensioning device to which the present invention is applied.
Figure 4 is an exploded perspective view showing a belt tensioning device to which the present invention is applied.
Figure 5 is an installation state showing an example of installation of the belt tensioning device to which the present invention is applied.
Figure 6 is an installation state showing another installation example of the belt tensioning device to which the present invention is applied.
Figure 7 is an operating state showing the operation of the belt tensioning device to which the present invention is applied.

Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

The belt tensioning device of the present invention comprises a housing 100, a rotating shaft 200, a spiral spring 300, a rod 400 and a roller 500 as shown in Figures 2 to 7.

The housing 100 may provide a space for supporting and protecting the rotating shaft 200, the spiral spring 300, and the rod 400 in an assembled state, while the rod 400 may rotate at an angle. So that it is formed. One side of the housing 100, for example, the bracket is formed to be fixed to the frame of the vehicle, the engine, compressor or generator is installed.

As an example of the housing 100, as shown in FIGS. 2 to 4, the housing 100 includes a cap part 110, an edge part 120, and a panel part 130.

The cap part 110 is formed with a gutter so as to surround and support the outer surface of one end of the rotating shaft 200 in the coupled state, and a flange is formed at the edge of the gutter to cover the spiral spring 300.

At this time, the bearing 140 is formed in the cap portion 110 of the housing 100 so as to smoothly rotate the rotating shaft 200 while supporting the rotating shaft 200. The bearing 140 applies a needle roller bearing.

The edge part 120 is coupled to the flange rim of the cap part 100, and is cut at an angle so that the rod 400 rotates while surrounding the side surfaces of the rod 400 and the spiral spring 300. That is, the edge portion 120 to limit the rotation angle of the rod.

The panel unit 130 is coupled to the edge unit 120, and the other end of the rotation shaft 200 is coupled to the shaft, and is formed to cover the spiral spring 300. That is, the housing 100 protects the spiral spring 300 from being exposed to the outside by the flange of the cap 110 and the panel 130.

The rotation shaft 200 is coupled to the center of the housing 100, and rotates the rod 400 while rotating by the elastic force of the spiral spring 300. Therefore, the rotation shaft 200 is installed to rotate in a state supported by the housing 100, one end of the spiral spring 300 is coupled, while the key 400 is coupled to the rod 400. A key protrusion 210 is formed on the rotary shaft 200 to couple the key between the rotary shaft 200 and the rod 400, and a key groove 410 is formed on the rod 400.

The spiral spring 300 is installed in a state in which the rotating shaft 200 is wound, and both ends of the spiral spring 300 are fixedly coupled to the rotating shaft 200 and the housing 100, respectively. For example, one end of the spiral spring 300 is coupled to the edge portion 120 of the housing 100.

The spiral spring 300 can be installed freely regardless of the installation position or angle of the housing because the elastic force acts in both the unwinding direction and the winding direction when the rotating shaft rotates while the rotating shaft 200 is wound. In addition, since the elastic force of the spiral spring 300 acts in the rotational direction of the rotation shaft 200 or the rod 400, the elastic force acts on the entire rotation radius, thereby increasing the range for tension adjustment of the belt.

One end of the rod 400 is fixedly coupled to the rotation shaft 200, and the roller 500 is axially coupled to the other end of the rod 400. That is, the rod 400 rotates about the rotation shaft 200 to move the roller 500 in the circumferential direction so that the tension of the belt is controlled.

The roller 500 is formed to be in close contact with the belt while being axially coupled to the other end of the rod 400. Since the roller 400 is spaced apart from the housing 100 by the rod 400 by a predetermined distance, the roller 400 may be in close contact with the inside or the outside of the belt. That is, as shown in Figures 5 and 7 the roller 500 can be in close contact with the outer surface of the belt to adjust the tension, in this case the outer surface of the roller 500 should be formed flat. In addition, as shown in Figure 6 the roller 500 is in close contact with the inner surface of the belt to adjust the tension, in this case, the gear formed on the inner surface of the belt by forming a gear on the outer surface of the roller 500 Can rotate in conjunction with

According to the configuration of the present invention as described above by using the elastic force of the spiral spring 300 to have a long distance and the rotation of the elastic force, the range of tension adjustment is further widened and the installation position or angle is free.

In addition, since the range of tension adjustment is widened and is not restricted by the installation position or angle, it can be applied to all belts as well as flat belts.

100: housing 110: cap
120: edge portion 130: panel portion
140: bearing
200: axis of rotation 210: key projection
300: spiral spring
400: load 410: key groove
500: roller

Claims (4)

housing; A rotating shaft coupled to the center of the housing; A spiral spring installed in a state in which the rotating shaft is wound and fixed to both ends of the spiral spring, respectively; A rod having one end coupled to the rotation shaft; And a roller axially coupled to the other end of the rod, wherein the housing is provided with a trough so as to surround and support its outer surface in a state in which one end of the rotary shaft is axially coupled, and an edge of the trough A cap portion formed with a flange to cover the spring; An edge portion coupled to an edge of the flange, the edge portion being cut at an angle such that the rod rotates while surrounding the sides of the rod and the spiral spring; And a panel portion coupled to the edge portion to allow the other end of the rotation shaft to be coupled to the shaft and to cover the spiral spring, wherein the bearing is formed to surround and support the rotation shaft in the cap portion of the housing. In the installed belt tensioning device,
Key projection is formed on the rotating shaft, a key groove is formed in the rod belt tension adjusting device, characterized in that the mutual key coupling.
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