KR200277835Y1 - Coil Spring Axial Rotation Power Train - Google Patents

Abstract

The present invention relates to a shaft rotation power transmission device, in particular, when transmitting the rotational force of the driving shaft to the driven shaft, as well as the driven shaft located on the same rotation shaft as the driving shaft, It is to connect the main shaft and the driven shaft with a coil type spring of constant length so that the shaft can be combined.

In order to achieve the object of the present invention, a shaft 1 having a predetermined length in which a gear 1 is axially coupled to an outer periphery of the rear end and a plurality of housing bearings 2 are laid, and both ends of the shaft 3 are connected to each other. A square cylindrical shaft 6 which is inserted to protrude and is axially coupled to the rear end and one end of a coil spring 5 of a predetermined length is axially coupled to the front end thereof, and a surface 7 of the square cylindrical shaft 6. A plurality of roller bearings (8) externally circumscribed to guide the axial movement of the rectangular cylindrical shaft (6), and mounting means for the roller bearings (8) for axial rotation of the roller bearings (3). It is to provide a coil spring shaft power transmission device.

Description

Coil Spring Axial Power Transmission Device

The present invention relates to a shaft rotation power transmission device, in particular, when transmitting the rotational force of the driving shaft to the driven shaft, as well as the driven shaft located on the same rotation shaft as the driving shaft, It is to connect the main shaft and the driven shaft with a coil type spring of constant length so that the shaft can be combined.

In general, the power transmission device of the rotating shaft is coupled by coupling when the primary shaft and the driven shaft are located on the same axis, and connected by the gear group when the primary shaft and the driven shaft are located on the horizontal line. When it is located on this acute angle, it is connected by universal join to transmit the rotational power of the primary shaft to the driven shaft.

In this way, the power transmission device of the general rotary shaft appropriately selects various types of connection methods according to the position of the main shaft and the driven shaft, and accordingly, the disadvantage of having a connection mechanism for each connection method is required and the assembly expertise is required accordingly. There was a problem.

The present invention has been devised in view of the above problems, and by connecting the main shaft and the driven shaft with a coil spring, the main shaft and the longitudinal shaft without using a separate connection mechanism according to the various positions of the driven shaft to connect with the main shaft It is to make it easy to connect coaxial.

In order to achieve the above object, the present invention provides a shaft tube 3 having a predetermined length in which a cylindrical gear 1 is axially coupled to an outer circumferential edge of a rear end and a plurality of housing bearings 2 are arranged, and both ends of the shaft tube 3. And a angular cylindrical shaft 6 in which a disc 4 is axially coupled to the rear end and one end of a coil spring 5 of a predetermined length is axially coupled to the front end thereof, and a surface of the angular cylindrical shaft 6. 7) a plurality of roller bearings (8) externally circumscribed to guide the axial movement of the square cylindrical shaft (6), and roller bearings (8) for axially rotating the roller bearings (3). It is to provide a coil spring shaft power transmission device configured.

1 is a plan view showing the present invention.

2 is a cross-sectional view taken along line A-A 'of FIG.

3 is an assembly view showing the installation means of the roller bearing according to the present invention.

4 is a plan view showing an embodiment of the present invention.

***** Detailed description of symbols for important parts of the drawings *****

1: Gear 2: Housing Bearing 3: Shaft Tube

4: disc 5: coil spring 6: square coaxial

7: face 8: roller bearing 9: inserter

10: pin ball 11: pin axis

Referring to the configuration and the embodiment of the present invention in detail with reference to the accompanying drawings as follows.

1 is a plan view showing the configuration of the present invention, Figure 2 is a cross-sectional view showing the AA 'of Figure 1, Figure 3 is an assembly view showing the installation means of the roller bearing according to the present invention, Figure 4 is the present invention A schematic diagram showing an embodiment of.

1, 2 and 3, the constitution of the present invention comprises a shaft tube 3 having a predetermined length in which a gear 1 is axially coupled to an outer circumferential edge of a rear end and a plurality of housing bearings 2 are arranged. (3) is inserted into the protruding end of both ends and the disk 4 is axially coupled to the rear end and the end of the angular cylindrical shaft (6), one end of the coil spring (5) of a certain length is axially coupled to the square cylindrical shaft ( A plurality of roller bearings (8) which are external to each side (7) of 6) to guide the axial movement of the square cylindrical shaft (6), and the rollers (8) are installed to axially rotate the shaft bearing (3). It consists of the means for installing the bearing.

The installation means of the roller bearing is formed in a position symmetrical in the front / rear and up / down direction perpendicular to the rotation axis of the shaft tube 3 so that the roller bearing 8 is inserted as shown in Figure 2 and 3 One inserting hole 9, a pin hole 10 formed coaxially in the upper / lower central part of the inserting hole 9, and an upper / lower end inserted into the pin hole 10 with a roller bearing 8 in the center thereof. The pin shaft 11 is rotatably inserted to insert the roller bearing 8 into the insertion hole 10.

The prismatic cylindrical shaft 6 and the coiled spring 5 are permanently coupled by welding, or a predetermined length of both ends of the coil spring 5 is formed in the cross-sectional shape of the prime shaft 6 and the driven shaft 12, It is preferable to couple both ends of the coil spring 5 to each shaft with bolts 15.

The diameter of the pin hole 10 is formed so that the pin shaft 11 can be fitted by forcibly fitting, ie hitting with a constant force.

The present invention configured as described above, as shown in FIG. 4, first secures the housing bearing 2 by fastening the bolt-nut method to the fixing member, and the motive gear 13 formed at the end of the rotating shaft 14 of the driving motor (not shown). ) Is combined with the gear (1).

And one end of the driven shaft 12 is coupled to the tip of the coil spring (5).

When the driving motor (not shown) is operated in such a state, the rotational force is transmitted to the rotating shaft 14-the primary gear 13-the gear 1, and at the same time as the rotation of the gear 1, the shaft tube 3 and the square shape. As the main shaft 6 and the coil spring 5 are rotated, they are transmitted to the driven shaft 12 having one end coupled to the tip of the coil spring 5.

At this time, even if the position of the driven shaft 12 is not located on the same axis as the square shaft 6 as the driven shaft 12a, 12b, that is, the driven shaft 12, 12a, 12b is Although it is located at various positions, such as 45 degrees, 90 degrees, and 180 degrees, which are not in line with the rotation axis of the circular shaft 6, the flexible spring of the coil spring 5 can be easily connected to the square circular shaft 6. It is possible to receive the rotational power.

Further, the square cylindrical shaft 6 is reciprocated by a constant length "d1" in the axial direction by the guide of the roller bearing 8, and according to the position of the driven shaft 12, 12a, 12b of the coil spring 5 You can make the connection smooth.

And the advancing distance of the said rectangular drive shaft 6 is limited by the disk 4, and can smoothly couple the coil spring 5 and the driven shafts 12, 12a, and 12b in the distance "d1".

As described above, the present invention is connected to the driven shaft and the driven shaft by a coil spring, so that the driven shaft on the same axis as the driven shaft without the use of separate complicated connecting means, ie coupling connection or universal joint and gear group And it is a very useful design that can easily connect the driven shaft on the multi-axis axis.

Claims (3)

A shaft tube 3 having a predetermined length in which the gear 1 is axially coupled to the outer periphery of the rear end and a plurality of housing bearings 2 are arranged; The square tube shaft 6 is inserted into the shaft tube 3 so that both ends protrude, and the disk 4 is axially coupled to the rear end, and one end of the coil spring 5 of predetermined length is axially coupled to the front end thereof. A plurality of roller bearings 8 circumscribed to the respective surfaces 7 of the rectangular cylindrical shaft 6 to guide the axial movement of the rectangular circular shaft 6; Coil spring shaft rotational power transmission device, characterized in that consisting of the installation means of the roller bearing for installing the roller bearing (8) to be axially rotated in the shaft tube (3). The method of claim 1, The installation means of the roller bearing is an insertion hole (9) formed in a position symmetrical in the front / rear and up / down direction perpendicular to the rotation axis of the shaft tube (3) so that the roller bearing (8) is inserted; A pin hole 10 formed coaxially in the upper / lower central part of the insertion hole 9, The upper and lower ends are inserted into the pin hole 10 and the roller bearing 8 is inserted in the center to form a pin shaft 11 rotatably inserting the roller bearing 8 into the insertion hole 10. Spring axial rotation power train. The method of claim 2, Both ends of the coil spring (5) is a coil spring shaft rotational power transmission device, characterized in that fastening with a bolt (15) to the square cylindrical shaft (6) and the driven shaft (12, 12a, 12b).