JPH0112013Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a flexible coupling that connects a driving device and a driven device, and more particularly to an insulated coupling that electrically insulates the driving device and the driven device.

Conventionally, flexible couplings as shown in FIGS. 1 and 2 have been used. This flexible coupling connects a motor 1, which is a driving device, and a pump 2, which is a driven device, and is composed of a motor-side hub 3, a pump-side hub 4, a center spool 5, a disk pack 6, etc. has been done.

Both hubs 3 and 4 are fitted onto ends of rotating shafts, respectively, and have flanges 3a and 4a formed therein.
A cylindrical center spool 5 is provided between the hubs 3 and 4, and flanges 5a are formed at both ends of the center spool 5, facing the flanges 3a and 4a. There is a disk between this flange 5a and flanges 3a and 4a.
Pack 6 is being held. This disk pack 6 is formed by laminating annular stainless steel plates.

The flanges 3a, 4a, 5a and the disk pack 6 are fastened together with eight bolts 7 arranged as shown in FIG. Bushes 9a, 9b and a spacer 10 are interposed between the bolt 7 and the flanges 3a, 4a, 5a, disk pack 6 and nut 8, respectively, and half of the bolts 7 are attached to the center spool 5.
The other half of the bolts 7 fasten the flanges 3a, 4a of both hubs 3, 4 and the disk pack 6. Therefore, the elasticity of the disk pack 6 absorbs the eccentricity of the rotating shafts of the motor 1 and pump 2, thereby transmitting power.

By the way, in such a flexible coupling, since motor 1 and pump 2 are electrically connected, stray current from motor 1 is transferred to pump 2.
There was a risk that electrolytic corrosion would occur in the pump 2. Therefore, there has been a demand for something that can electrically insulate the motor 1 and pump 2.

In order to satisfy such a demand, it is conceivable to divide the center spool 5 into two parts in the axial direction and connect the divided parts with an electrically insulating material. In this configuration, centering to align the axes of the two-divided center spool 5 is extremely troublesome, but in fact, accurate centering cannot be performed, and center runout ( eccentricity) occurs.

Such center run-out of the center spool 5 is caused by the mismatch between the axes of the hub 3 of the driving device and the hub 4 of the driven device, and the flexibility secured by the elasticity of the disk pack 6 is reduced. This will exceed the allowable range of the tie, and it will no longer be able to perform its function as a flexible coupling. Also,
Even if the center spool 5 is accurately centered, there is a risk that spontaneous center runout may occur during use.

The present invention was developed in consideration of the above circumstances, and its purpose is to connect the driving side equipment and the driven side equipment in an electrically insulated state, and to connect the connecting part. It is configured such that centering can be performed easily and reliably, and a predetermined flexibility can be ensured. The object of the present invention is to provide a flexible insulated coupling.

To achieve this objective, the present invention is constructed as follows. In other words, in a flexible coupling in which a hub fixed to a driving device and a hub fixed to a driven device are connected by a center spool through a disk pack, there is a split part in the middle. The split part has a center spool formed with a flange on its outer circumferential surface and a fitting recess formed on its inner circumferential surface. An insulating ring formed of an electrically insulating material to maintain electrical insulation of the divided portion, and an insulating bolt that penetrates the flange of the center spool and is fixed by interposing an insulating gasket between the flanges. This is what we have in place.

An embodiment of the present invention will be described below with reference to FIG. In FIG. 3, the same reference numerals as in FIGS. 1 and 2 indicate the same or corresponding parts.

A dividing portion 20 is formed in the axially central portion of the center spool 5, and the center spool 5 is divided in the axial direction by this dividing portion 20. Flanges 2 are provided on the outer circumferential surface of the divided portion 20, facing each other.
1 and 21 are formed, and fitting recesses 22 and 22 are formed on the inner peripheral surface of the divided portion 20.

The fitting recess 22 is formed into a ring shape concentric with the axis of the center spool 5 by precision machining such as milling. An insulating ring 23 is fitted into the fitting recess 22, and in a state where the insulating ring 23 is fitted into the fitting recess 22, the divided part 2
The axes of the center spool 5 at 0 are made to coincide with each other, and the flanges 21, 21 are maintained in a non-contact state. The insulation ring 23
is made of a hard electrically insulating material such as phenolic resin, and is designed to electrically insulate the motor 1 and the pump 2. Further, a gasket 24 made of phenolic resin is interposed in the gap between the flanges 21, 21.

A plurality of insulating bolts 25 are provided passing through the flanges 21, 21 and the gasket 24, and nuts 26 are screwed into the insulating bolts 25 to be fastened. The insulating bolt 25 is conventionally known, and the outer periphery of the body of the bolt is lined with a layer of fluororesin to maintain electrical insulation. In addition, the head of the insulating bolt 25, the nut 26 and the flange 2
An insulating washer 27 is interposed between it and 1 to maintain electrical insulation. This insulating washer 27 is made of FRP.

The device according to the embodiment having the above configuration has the following effects.

Since the body of the insulating bolt 25 is lined with fluororesin, the dimensional accuracy in the radial direction is poorer than, for example, a reamer bolt. Therefore, with the insulating bolt 25, it is impossible to align the axes of the center spool 5 in the divided portion 20, that is, to perform so-called centering. However, since the insulating ring 23 is fitted into the fitting recess 22, the centering of the center spool 5 in the divided portion 20 can be reliably performed using the insulating ring 23, and once centered, , spontaneous center runout (eccentricity) does not occur. Therefore, the discrepancy between the relative axes of the motor 1 and the pump 2 can be kept within the allowable range of flexibility ensured by the elasticity of the disk pack 6, making the function as a flexible coupling effective. can be demonstrated.

Also, when disassembling and assembling the divided portion 20, the centering work of the center spool 5 is performed in the fitting recess 2.
2 only needs to be fitted with the insulating ring 22, making the centering work extremely simple.

As explained above, according to the present invention, it is possible to connect the driving side device and the driven side device in an electrically insulated state, and also to easily and reliably align the axes of the divided portions of the center spool. , its practical effects are great.

[Brief explanation of the drawing]

Figures 1 and 2 are diagrams showing conventional examples.
The figure is a longitudinal sectional view, Figure 2 is a view taken in the direction of arrow A in Figure 1, and Figure 3 is a longitudinal sectional view.
The figure is a longitudinal sectional view showing an embodiment of the present invention. 1... Motor (driving side equipment), 2... Pump (driven side equipment), 3, 4... Hub, 5... Center spool, 6... Disk pack, 20...
Divided portion, 21... flange, 22... fitting recess,
23... Insulation ring, 24... Gasket, 25
...Insulating bolt.

Claims (1)

[Scope of utility model registration request] A flexible coupling in which a hub fixed to a driving device and a hub fixed to a driven device are connected by a center spool through a disk pack, which has a split part in the middle and has a split part in the middle. A center spool with a flange formed on the outer circumferential surface of the divided part and a fitting recess formed on the inner circumferential surface, and a hard electrical insulator that is fitted into the fitting recess of the center spool to align the axis of the center spool. and an insulating bolt that penetrates the flanges of the center spool and is fixed with an insulating gasket interposed between the flanges. An insulating coupling ring characterized by: