JPS58132602A - Measuring device of abraded quantity in stem driving device - Google Patents

Abstract

PURPOSE:To prevent accidents due to abrasion of screw threads, by providing an auxiliary nut, which is rotated in synchronization with a driving nut, so that the auxiliary nut can be displaced in the axial direction of a stem, coupling the auxiliary nut with the bottom of the thread of the stem, and detecting the amount of the abrasion of the bottom of the thread of the stem. CONSTITUTION:The auxiliary nut 18 of a measuring device is provided with a gap in the axial direction of the stem and can be rotated in synchronization with the driving nut 16 through an adapter 17. Since the auxiliary nut 18 is only coupled with the stem 6', said nut 18 does not receive the load of the stem 6' from said coupling part. Therefore, even though the screw thread of the driving nut 16 is abraded due to the opening and closing operation of a gate for a long time, the screw thread of the auxiliary nut 18 is hardly abraded. Thus the accidents due to the abrasion of the screw threads can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a stem drive system which is used for opening and closing externally threaded pulp or water gates, and is configured to move a stem equipped with thread grooves in the axial direction by rotating a drive nut. The present invention relates to an apparatus for measuring wear amount of an apparatus.

At pumping stations, sewage treatment plants, etc., gates are installed at the outflow, inlet, and outlet to cut off the flow of water, restrict the flow rate, or change the direction of the flow.

These gates use pumped pulp such as gate valves, globe valves, butterfly valves, ball valves, etc., as well as heavy water gates, but due to repeated opening and closing over many years, the stem that drives the gates to open and close has deteriorated. The thread of the drive nut that fits into the thread groove of the valve stem (valve stem) becomes worn.

FIG. 1 shows an example of a motor-driven stem drive device.

A pinion 2 on the shaft of the motor (1) rotates a worm 4 via a gear 3. The worm wheel 5 that meshes with the worm 4 holds the pulp stem 6 which is opened and closed.
It is designed to be driven in the axial direction perpendicular to the page.

Next, based on FIG. 2 showing the cross section taken along line A-A in FIG. 1,
A conventional stem drive device will be explained.

The worm wheel 5 has an appropriate clutch member (force (8)
The drive sleeve 9 is connected to the drive sleeve 9 via the drive sleeve 9. The drive sleeve 9 has a long cylindrical shape and is attached to the stem 6.
is mated to. The drive nut 10 is spline-fitted with the drive sleeve 9 and locking nut 11.
It is positioned with respect to the housing 12 by.

In addition, 13 is a housing cover, and a drive nut 10
It can be opened for replacement. Further, the opening degree indicator 14 is for indicating the opening degree of the gate 15 by the stem 6.

In the conventional stem drive device configured as described above, when the worm wheel 5 rotates, the drive sleeve 9 is rotated in a predetermined direction via the clutch members 7 and 8. The drive nut 10, which is rotated by the spline portion of the drive sleeve 9, drives the stem 6 in the vertical direction depending on the direction of rotation thereof, thereby opening and closing the gate 15.

In the conventional device described above, since the drive nut 10 is driven by being fitted with the stem 6, the threads of the drive nut 10 are worn out due to gate opening and closing operations over many years, but the fitting part between the stem 6 and the stem nut 10 is Since it cannot be directly observed,
Eventually, an accident such as the gate 15 falling due to the weight of the gate 15 and the stem (6) may occur.

Therefore, check the thread wear of the drive nut 10,
In order to prevent such accidents, it is necessary to remove the housing cover 13 one by one, which is troublesome and prevents smooth opening and closing of the gate.

The present invention has been made to eliminate the above-mentioned drawbacks, and to prevent accidents caused by wear of the threads of the drive nut. The amount of wear can be easily detected.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be explained using a stem drive device driven by a motor as shown in the drawings.

In FIG. 3, a gate 15' that can be opened and closed is fixed to one end of the stem 6'. Drive sleeve 9
' is spline-fitted with the drive nut 16, and
It is spline-fitted to a sub-nut 18 via an adapter 17. That is, the adapter 17 is spline fitted to both the secondary nut 18 and the drive sleeve 9'. The width nut 18 has a load direction (
It is pulled by a spring 19 in the same direction as the lower part of the drawing.

The drive nut 16 is positioned by a locking nut 11.11 and is adapted to fit in a fixed axial position relative to the stem 6 and to be driven by rotating the stem 6. On the other hand, the secondary nut 18 has a space in the axial direction of the stem (in the upper and lower directions in the figure), and is configured to rotate in synchronization with the drive nut 16 via the adapter door.

Therefore, the auxiliary nut white 8 only fits into the stem 6', and does not receive any load from the stem 6' through this fitting portion.

In addition, 12 is a housing, and 13'μ housing cover.

In the device of the present invention configured as described above, the drive sleeve 9
', the drive nut 16 rotates and the stem 6
When driving up and down, the secondary nut 18 does not receive any load from the stem 6' due to the loosely fitted adapter 17.

Therefore, since the drive nut 16 mostly contacts the upper surface of the thread groove formed in the stem 6', the upper surface of the thread of the drive nut 16 gradually wears out. In other words, the threads of the drive nut 16 are worn out due to long years of gate opening and closing operations, but the threads of the sub-nut 18 are hardly worn out.

As wear of the drive nut 16 progresses, the stem 6' is displaced downward compared to the state in which the threads were not worn initially.

However, since the secondary nut 18 is not subjected to any load between it and the stem 6 and is not substantially worn out, the spring 19 moves the stem 6 downward by the same amount as the wear of the drive nut 16. Move to the position where it is pulled.

In the stem drive device driven in this way,
Even if the threads of the drive nut 16 are worn out and no longer engage, the sub-nut 18 is still engaged with the stem 6, so if the sub-nut 08 is provided with a fall prevention measure, the gate 15' will not fall due to its own weight. Accidents such as accidents can be prevented.

In the embodiment shown in FIG. 6, a large number of annular grooves (A) are provided at regular intervals on the outer surface of the second sub-nut 18, as shown in FIG. , annular groove (
The amount of displacement of the auxiliary nut 18 is converted into the amount of rotation by the pinion 21 meshed with the nut 18.

The rotation of the shaft 22 integrally formed with the pinion 21 is sequentially increased in speed through the gear 24, pinion 25, gear 26, and pinion 27 through the torsion spring 23.
The information is transmitted to a detection unit consisting of a remote transmitter 28, a pointer 29, a dial 30, etc.

Incidentally, the detection section has a window 32 formed at the cuckoo (-31), and this window 32 is fixed to the cuckoo 33 at the cuckoo.

Further, the bracket 34 of the housing 12' is inserted between the adapter 17 and the sub-nut 18, has a pin 35 attached thereto for setting the initial position, and is covered with a cover 56.

With this configuration, the amount of wear on the thread of the drive nut 16 is detected by displaying the amount of displacement of the sub-nut in the stem load direction using the pointer 29, etc., and the time to replace the nut with a new one is determined. It becomes easier to do so.

Furthermore, if a potentiometer or the like is used as the remote transmitter 28 to convert the rotation angle into an electrical signal, the amount of wear on the threads of the drive nut 16 can be observed even in a central control room or the like.

In the above embodiment, the amount of wear on the screw thread converted into the rotation angle by the gears and pinions 24, 25, 26°27 is
Since the speed is increased and transmitted to the pointer 29, even a slight wear amount of about 0.5n on the thread of the drive nut 16 can be read on site.

Note that the pin 5 is to be removed using the cover 36 when the installation is completed on site, but this pin 35 maintains a constant distance between the adapter 17 and the sub-nut t181. , which can be installed on-site in its factory-shipped condition.

[BRIEF DESCRIPTION OF THE DRAWINGS] Fig. 1 is a conceptual diagram showing an example of a stem drive device, Fig. 2 is a sectional view taken along line A--A in Fig. 1 showing main parts of a conventional device, and Fig. 3 is a diagram showing the main parts of a conventional device. FIG. 4 is a sectional view showing the main parts of the inventive device.
FIG. 4 is a sectional view taken along line BB in FIG. 3; (1) Motor, (2) Pinion, (3) Gear, (4) Worm, (5) Worm wheel, (6), (6')
Stem, (7), (8) Clutch member, (91, (9)
') Drive sleeve, α [drive nut, CIt)
, (11') locking nut, α2. (12')-・
Uzing, 1st crime (13') - Uzing copper, ■ Opening indicator, Q5), (15') gate, Q61 drive nut, Q7) adapter, 08 sub-nut, (ll spring,
Four-day cylinder rack, Cυ pinion, (2 moat toshiyo/spring > (24) gear, (2ω pinion, (c) gear, (
27+ pinion, (to) remote transmitter, (c) pointer, (to) dial, 00 cover, 0 hit India - 1 (c)
Cover, (3-point bracket, C35) bottle, (g) cover. Rope 53 6' 1 8- Figure 4

Claims (2)

[Claims] (1) A drive nut that rotates at a fixed position in the axial direction is fitted into the thread groove of the stem, which has a thread groove on the outer periphery and is movable in the axial direction to hang, thereby driving the stem. In the stem drive device, a sub-nut that rotates in synchronization with the drive nut is displaceable in the axial direction of the stem and is fitted into a thread groove of the stem,
The amount of wear of the thread groove of the stem is detected based on the displacement of the fitting position between the sub-nut and the stem caused by the wear between the thread of the drive nut and the thread groove of the stem. A wear measurement device for a stem drive device. (2) An annular groove pinion attached to an appropriate position on the outer surface of the sub-nut is fitted, and the amount of wear on the thread groove of the stem is detected based on the amount of rotation of the pinion accompanying the axial displacement of the sub-nut. The device according to claim (1), characterized in that: