CN116907403B - Continuous displacement measuring device for large-stroke sliding assembly of synchronous automatic clutch - Google Patents

Abstract

The invention provides a continuous displacement measuring device for a large-stroke sliding component of a synchronous automatic clutch, and belongs to the technical field of measuring devices. The invention comprises the following steps: the shifting fork is arranged on the large-stroke measuring ring of the sliding component; the upper part of one end of the mandrel is fixed on the housing of the synchronous automatic clutch and can rotate; one end of the connecting rod is rotationally connected with the shifting fork, and the other end of the connecting rod is connected with the other end of the mandrel and can drive the mandrel to rotate; and the shaft head of the angle sensor is fixed at the top end of the mandrel. According to the invention, the axial linear displacement of the sliding component is converted into the angular displacement of the connecting rod, and then the rotation angle of the shaft head of the sliding component is measured through the angle sensor, so that the axial linear displacement of the sliding component is calculated, the continuous displacement measurement of the large-stroke sliding component of the synchronous automatic clutch can be realized, the original continuous displacement monitoring which can only be used for monitoring two states is updated to the full-stroke continuous displacement monitoring, and very valuable monitoring data are provided for the safe operation and fault diagnosis of the high-power synchronous automatic clutch.

Description

Continuous displacement measuring device for large-stroke sliding assembly of synchronous automatic clutch

Technical Field

The invention relates to the technical field of measuring devices, in particular to a continuous displacement measuring device of a large-stroke sliding component of a synchronous automatic clutch.

Background

The synchronous automatic clutch is a high-power-density and high-reliability tooth clutch which is automatically engaged and disengaged by means of the change of the rotation speeds of an input end and an output end, and is widely applied to the power transmission fields of ships, metallurgy, chemical industry, power generation and the like. The synchronous automatic clutch mainly comprises an input assembly, a sliding assembly and an output assembly, and the synchronous automatic clutch is in an engaged or disengaged state, which is a key operation parameter in practical application.

The synchronous automatic clutch may be judged to be in an engaged state or a disengaged state by monitoring the axial position of the slip assembly. Currently, a measurement device for monitoring the position of a clutch slip assembly generally employs a method of providing two radially arranged eddy current proximity switches at the engaged and disengaged positions of the clutch slip assembly. When the clutch slip assembly is in the engagement position, a proximity switch of the engagement position outputs an effective signal; when the clutch slip assembly is in a disengaged position, a proximity switch in the disengaged position outputs a valid signal; when the clutch sliding assembly is in an engaged and disengaged intermediate position, no effective signal is output by the two proximity switches, and the specific position and the movement state of the clutch sliding assembly cannot be determined; when the clutch fails to engage or disengage, accurate position data of the clutch slip assembly cannot be obtained, and accurate diagnosis of the failure can not be made.

As shown in fig. 1, the basic structure of the synchronous automatic clutch in the prior art is composed of a clutch output assembly 100, a clutch slip assembly 200 and a clutch input assembly 300, and the axial movement of the clutch slip assembly 200 realizes the engagement and disengagement of the synchronous automatic clutch. The position of the clutch slip assembly 200 is typically monitored by a radially disposed proximity switch, and when the clutch slip assembly 200 is moved to the engaged position, the measuring ring 201 triggers the engaged position proximity switch 500 to output a signal representative of synchronous automatic clutch engagement, as shown in FIG. 2. When the clutch slip assembly 200 is moved to the disengaged position, the measuring ring 201 triggers the disengaged position proximity switch 400 to output a signal representing the synchronized automatic clutch disengagement, as shown in FIG. 1. The monitoring method has the defects that only two states of engagement or disengagement of the clutch slip assembly 200 can be displayed, the state in the middle of the two positions cannot be monitored, when the synchronous automatic clutch has engagement or disengagement faults, the position of the clutch slip assembly 200 cannot be judged, data cannot be provided for fault cause analysis, and the method is only suitable for the condition that the engagement/disengagement stroke of the slip assembly is short.

To solve the problem that the continuous displacement of the slip assembly cannot be monitored, an improved measurement method in the prior art is shown in fig. 3, and the axial displacement of the measurement ring 201 of the clutch slip assembly 200 is monitored by using the eddy current displacement sensors which are axially arranged, so that accurate continuous displacement measurement can be realized, and the displacement measurement range of the clutch slip assembly 200 can be improved by arranging two eddy current displacement sensors, namely, the eddy current displacement sensor 410 at the 1 disengaging position and the eddy current displacement sensor 510 at the 1 engaging position, in combination, as shown in fig. 3 and 4. However, even if two eddy current displacement sensors are combined, the method is only suitable for the condition that the engagement/disengagement stroke of the clutch slip assembly 200 is short, the diameter size of the eddy current displacement sensors is greatly increased along with the increase of the measured displacement stroke, and domestic and foreign data show that the displacement measurement range of the eddy current sensors with the diameter of 8mm is 2mm, and the displacement measurement range of the eddy current sensors with the diameter of 60mm is only 50mm. When the synchronous automatic clutch size is large due to a large increase in the transmitted torque, such as a combined combustion-steam cycle generator set clutch, a ship propeller shaft clutch, the engagement/disengagement stroke of the large stroke slip assembly 210 is around 80-130mm, and even larger as shown in fig. 5, it has a large stroke clutch output assembly 110, a large stroke slip assembly 210, and a large stroke clutch input assembly 310. As shown in fig. 6, in order to match the measurement space of the eddy current displacement sensor, the large-range eddy current displacement sensor 411 at the disengaged position and the large-range eddy current displacement sensor 511 at the engaged position are selected, or in order to match the measurement space of the large-range eddy current displacement sensor, the diameter of the large-range measuring ring 211 is required to be made large, resulting in waste of space and material. The measurement method using an axially arranged eddy current displacement sensor is therefore not suitable for large stroke slip assemblies. And because the operation environment of the synchronous automatic clutch is a splash oil pollution environment, the stroke of the sliding component cannot be measured by adopting an ultrasonic sensor.

Disclosure of Invention

In view of the above, in order to solve the technical problem that the continuous displacement of the sliding component cannot be monitored in the prior art, the invention provides a continuous displacement measuring device for the large-stroke sliding component of a synchronous automatic clutch, which converts the axial linear displacement of the sliding component into the angular displacement of a connecting rod, and then measures the rotation angle of a shaft head of the sliding component through an angle sensor, so that the axial linear displacement of the sliding component is calculated, the continuous displacement measurement of the large-stroke sliding component of the synchronous automatic clutch can be realized, and the original continuous displacement monitoring which can only monitor two states is updated to full-stroke continuous displacement monitoring, thereby providing valuable monitoring data for the safe operation and fault diagnosis of the high-power synchronous automatic clutch.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a synchronous automatic clutch large stroke slip assembly continuous displacement measurement device comprising:

a shift fork arranged on a large-stroke measuring ring of the sliding component;

a mandrel, one end of which is fixed on the cover shell of the synchronous automatic clutch and can rotate;

one end of the connecting rod is rotationally connected with the shifting fork, and the other end of the connecting rod is connected with the other end of the mandrel and can drive the mandrel to rotate;

the shaft head of the angle sensor is fixed at the top end of the mandrel;

when the synchronous automatic clutch is in a disengaging or engaging state, the large-stroke measuring ring moves to drive the shaft head to rotate through the connecting rod, and the angle sensor measures the rotation angle according to the rotation of the shaft head.

Preferably, the method further comprises:

a flange plate mounted on the housing;

the shaft sleeve is in interference connection with the flange plate;

the blanking cover is fixed on the flange plate;

the shaft sleeve is arranged outside the mandrel in a sealing manner, an annular cavity is formed between the shaft sleeve and the mandrel, the top end of the mandrel penetrates out of the flange plate to be located above the flange plate, and the blocking cover is arranged outside the top end of the mandrel in a sealing manner.

Preferably, the method further comprises:

one end of the oil inlet pipe is communicated with the annular cavity, and the other end of the oil inlet pipe is communicated with an oil inlet joint outside the flange plate;

lubricating oil in the oil inlet pipe lubricates the mandrel through the annular cavity.

Preferably, a first radial hole I, a second radial hole II and a first axial hole which are communicated with each other are formed in the mandrel;

a long hole is formed in the connecting rod;

a second radial hole and a second axial hole which are mutually communicated are formed in the shifting fork, and a ring groove communicated with the second radial hole is formed in a rotating shaft of the shifting fork;

and two ends of the long hole are respectively communicated with the first radial hole II and the annular groove.

Preferably, an oil distributing hole and a friction surface oil spraying hole are formed in the shifting fork, and the lubricating oil is sprayed out of the oil distributing hole and the friction surface oil spraying hole to lubricate the shifting fork and the friction surface between the shifting fork and the large-stroke measuring ring.

Preferably, a cavity is formed in the blanking cover;

and the shaft sleeve is provided with a drain hole for draining the lubricating oil leaked into the cavity.

Preferably, the axis of the spindle is parallel and non-coincident with the axis of the fork, while the axis of both is spatially perpendicular to the axis of rotation of the synchronous automatic clutch.

Compared with the prior art, the invention has the following beneficial effects:

according to the continuous displacement measuring device for the large-stroke sliding component of the synchronous automatic clutch, provided by the invention, the axial linear displacement of the sliding component is converted into the angular displacement of the connecting rod, and then the rotation angle of the shaft head of the sliding component is measured through the angle sensor, so that the axial linear displacement of the sliding component is calculated, the continuous displacement measurement of the large-stroke sliding component of the synchronous automatic clutch can be realized, and the original continuous displacement monitoring of the large-stroke sliding component of the synchronous automatic clutch can be updated to the full-stroke continuous displacement monitoring from the original two states, so that very valuable monitoring data are provided for the safe operation and fault diagnosis of the high-power synchronous automatic clutch.

Drawings

FIG. 1 is a prior art measurement of slip assembly state using a proximity switch with a clutch in a disengaged state;

FIG. 2 is a prior art measurement of slip assembly state using a proximity switch with a clutch in an engaged state;

FIG. 3 is a prior art measurement of slip assembly position using an eddy current displacement sensor with the clutch in a disengaged state;

FIG. 4 is a prior art measurement of slip assembly position using an eddy current displacement sensor with a clutch in an engaged state;

FIG. 5 is a schematic diagram of a prior art high power synchronized automatic clutch configuration;

FIG. 6 is a prior art scheme for measuring the position of a large travel slip assembly using a wide range eddy current displacement sensor.

Fig. 7 is a perspective view of the present invention.

FIG. 8 is a schematic diagram of the connection of an angle sensor, a blanking cover, a flange plate, etc.;

FIG. 9 is a schematic cross-sectional view of a large travel slip assembly disengaged condition measured using the teachings of the present invention;

FIG. 10 is an X-ray view of FIG. 9;

FIG. 11 is a schematic cross-sectional view of a large travel slip assembly coupling condition measured using the teachings of the present invention;

FIG. 12 is a schematic view of the rotation angle of the present invention;

FIG. 13 is a schematic view of a lubrication circuit of the present invention;

FIG. 14 is a cross-sectional view taken in the direction A-A of FIG. 13;

FIG. 15 is a cross-sectional view taken in the direction B-B of FIG. 14;

FIG. 16 is a cross-sectional view of the present invention with an oil drain hole;

in the drawings, 100. A clutch output assembly, 110. A large range clutch output assembly, 200. A clutch slip assembly, 201. A measuring ring, 210. A large range slip assembly, 211. A large range measuring ring, 300. A clutch input assembly, 310. A large range clutch input assembly, 400. A disengagement position proximity switch, 410. A disengagement position eddy current displacement sensor, 411. A disengagement position large range eddy current displacement sensor, 500. An engagement position proximity switch, 510. An engagement position eddy current displacement sensor, 511. An engagement position large range eddy current displacement sensor, 600. A large range slip assembly continuous displacement measuring device, 610, flange plate, 620, bushing, 621, annular cavity, 622, oil drain hole, 630, blanking cap, 631, cavity, 640, mandrel, 641, first radial hole I, 643, first radial hole II, 642, first axial hole, 650, connecting rod, 651, slot, 660, shift fork, 661, annular groove, 662, second radial hole, 663, second axial hole, 664, primary oil drain hole, 665, tertiary oil drain hole, 666, friction surface oil drain hole, 667, secondary oil drain hole, 670, oil drain pipe, 680, angle sensor, 681, stub, 682, set screw, 690, compression ring, 691, screw, 700, housing, 710.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present invention are within the protection scope of the present invention.

In the description of the present invention, it should be noted that the positional or positional relationship indicated by the terms such as "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "configured to," "engaged with," "connected to," and the like are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

In view of the above-described deficiencies of the prior art (shown in fig. 1-6), the present invention provides a synchronous automatic clutch long stroke slip assembly continuous displacement measurement device 600, as shown in fig. 7-12, comprising:

a fork 660 provided on the large-stroke measuring ring 211 of the slip assembly, preferably, the fork 660 is caught on the large-stroke measuring ring 211 of the synchronous automatic clutch slip assembly;

a spindle 640 having an upper end fixed to the housing 700 of the automatic synchronizer clutch and rotatable;

the connecting rod 650, one end of which is rotationally connected with the shifting fork 660, preferably, the shifting fork 660 is fixed through two hexagonal thin nuts after passing through the connecting rod 650, so as to ensure that the axial movement of the shifting fork 660 is minimum, and meanwhile, the shifting fork 660 can flexibly rotate around the axis of the shifting fork, and the other end of the shifting fork is connected with the other end of the mandrel 640, preferably, in interference connection, and can drive the mandrel 640 to rotate;

an angle sensor 680, wherein a shaft head 681 is fixed at the top end of the spindle 640, preferably the shaft head 681 is inserted into a hole at the top end of the spindle 640 and fixed by a set screw 682, specifically, a radial hole is formed on the plug 630, and the radial hole is axially aligned with the installation position of the set screw 682;

when the synchronous automatic clutch is in a disengaged or engaged state, the large-stroke measuring ring 211 is moved to drive the spindle head 681 to rotate through the connecting rod 650, and the angle sensor 680 measures the rotation angle according to the rotation of the spindle head 681, specifically:

when the large-stroke measuring ring 211 moves axially, the shifting fork 660 is driven to move along the rotation axis 710 of the synchronous automatic clutch, meanwhile, the shifting fork 660 moves tangentially along the large-stroke measuring ring 211, after the shifting fork 660 moves, the mandrel 640 is driven to rotate, so that the angle sensor 680 is driven to rotate the mandrel 681, and the angle sensor 680 measures the rotation angle of the mandrel 640 in real time.

In the present invention, further comprising:

a flange plate 610 mounted on the housing 700;

a sleeve 620, which is in interference connection with the flange plate 610;

a blanking cover 630 fixed to the flange plate 610, preferably fixed to the flange plate 610 by screws 691;

the shaft sleeve 620 is sealed and sleeved outside the mandrel 640, an annular cavity 621 is arranged between the shaft sleeve 620 and the mandrel 640, the top end of the mandrel 640 penetrates out of the flange plate 610 and is positioned above the flange plate 610, and the blocking cover 630 is sleeved outside the top end of the mandrel 640;

after the spindle 640 passes through the shaft sleeve 620, the spindle 640 is preferably fixed by two hexagonal thin nuts, and the spindle 640 can flexibly rotate in the shaft sleeve 620 while the axial movement of the spindle 640 is minimized by adjusting the two hexagonal thin nuts.

In view of the above, as shown in fig. 8, the housing of the angle sensor 680 is preferably mounted against the cover 630 and is pressed by 4 screws 691 with a pressing ring 690.

In the continuous displacement measuring device for the large-stroke slip component of the synchronous automatic clutch provided by the invention, in order to facilitate calculation, when the mounting hole of the displacement measuring device of the housing 700 of the synchronous automatic clutch is designed, the plane formed by the axis of the mandrel 640 and the axis of the shifting fork 660 is vertical to the rotation axis 710 of the synchronous automatic clutch when the synchronous automatic clutch is in a disengaged or engaged state. As shown in fig. 9 to 12, taking an example that a plane formed by an axis of the spindle 640 and an axis of the fork 660 is perpendicular to the axis of rotation 710 of the synchronous automatic clutch when the synchronous automatic clutch is disengaged, the angle sensor 680 in fig. 12 measures the feedback angle as α, and the angle α is a constant value, which is determined by an initial installation state of the angle sensor 680; after the synchronous automatic clutch starts to engage, the large-stroke measuring ring 211 moves to the engaged position, the angle sensor 680 measures the feedback angle β, the angle β is a variable, the distance L between the axis of the spindle 640 and the axis of the fork 660 is determined by the position of the large-stroke measuring ring 211, the distance L is a constant value, and the real-time displacement S of the large-stroke slip assembly 210 is determined by the structure of the displacement measuring device, and can be calculated according to the following formula:

S=L×sin(β-α)。

as shown in fig. 13, to lubricate the spindle 640, to avoid the abrasion seriously affecting the service life, in the present invention, it further includes:

an oil inlet pipe 670 having one end communicating with the annular chamber 621 and the other end communicating with an oil inlet joint outside the flange plate 610;

the lubricating oil in the oil inlet pipe 670 lubricates the spindle 640 through the annular cavity 621, specifically:

the oil inlet pipe 670 is connected between the flange plate 610 and the shaft sleeve 620, lubricating oil is led into the oil inlet pipe 670 through an oil inlet joint outside the flange plate 610, two ends of the matching position of the shaft sleeve 620 and the mandrel 640 are of sealing structures, the two ends are respectively sealed through two O-shaped rings, the middle part of the sealing structures is a ring cavity 621 with the radius difference of 3mm, and the lubricating oil in the oil inlet pipe 670 can enter the ring cavity 621 to lubricate the mandrel 640 so as to avoid abrasion of the mandrel 640, and the service life of the sealing structures is prolonged.

In the case of a high power (more than 90 MW) generator set synchronous automatic clutch application, the linear speed of the contact position of the fork 660 and the large-stroke measuring ring 211 can reach 150m/s, and in order to ensure that the fork 660 is not worn, a sufficient amount of lubricating oil is supplied to the friction surface between the fork 660 and the large-stroke measuring ring 211. In order to solve the lubrication technical problem of the contact position of the fork 660 and the large-stroke measuring ring 211, as shown in fig. 13-15, in the present invention, a first radial hole 641, a second radial hole 643 and a first axial hole 642 which are mutually communicated are formed on the mandrel 640, wherein the first radial hole 641 is formed near the middle, and the second radial hole 643 is formed near the bottom;

a long hole 651 is formed in the connecting rod 650;

a second radial hole 662 and a second axial hole 663 which are mutually communicated are formed in the shifting fork 660, and a ring groove 661 communicated with the second radial hole 662 is formed in the rotating shaft of the shifting fork 660;

both ends of the long hole 651 are respectively communicated with the first radial hole two 643 and the annular groove 661.

In the present invention, the oil distributing hole and the friction surface oil spraying hole 666 are formed in the fork 660, the lubricating oil is sprayed out from the oil distributing hole and the friction surface oil spraying hole 666 to lubricate the fork 660 and the friction surface between the fork 660 and the large-stroke measuring ring 211, wherein the oil distributing hole in the fork 660 can be 1 first-stage oil distributing hole 664, 2 second-stage oil distributing holes 667 and 6 third-stage oil distributing holes 665, and the friction surface oil spraying hole 666 can be 6.

In the present invention, the blocking cover 630 has a cavity 631 therein;

since the annular cavity 621 with the radius difference of 3mm formed between the shaft sleeve 620 and the mandrel 640 is supplied with lubricating oil with a certain pressure, even if two O-rings are adopted for sealing, after long-time operation, lubricating oil leaks into the cavity 631 in the blanking cover 630 from the sealing positions of the O-rings, after the lubricating oil is fully accumulated in the cavity 631, a certain pressure is established, and the lubricating oil leaks out from the installation gap between the mandrel 640 and the blanking cover 630 and the installation gap between the blanking cover 630 and the flange plate 610, so that the lubricating oil leaks out of the housing 700 of the synchronous automatic clutch, and the environment is polluted. In order to solve the problem, as shown in fig. 16, the present invention adopts a technical scheme that an oil drain hole 622 is formed in a shaft sleeve 620, so as to drain the lubricating oil stored in a cavity 631 in time to the inside of a housing 700 of the synchronous automatic clutch, thereby avoiding environmental pollution caused by leakage of the lubricating oil.

In the present invention, the axis of the spindle 640 is parallel to and not coincident with the axis of the fork 660, and both axes are spatially perpendicular to the synchronous automatic clutch rotation axis 710, i.e., the plane formed by the axis of the spindle 640 and the axis of the fork 660 is spatially perpendicular to the rotation axis.

The above is only a preferred embodiment of the present invention; the scope of the invention is not limited in this respect. Any person skilled in the art, within the technical scope of the present disclosure, may apply to the present invention, and the technical solution and the improvement thereof are all covered by the protection scope of the present invention.

Claims (1)

1. A synchronous automatic clutch large stroke slip assembly continuous displacement measuring device, comprising:

a shift fork arranged on a large-stroke measuring ring of the sliding component;

a mandrel, one end of which is fixed on the cover shell of the synchronous automatic clutch and can rotate;

one end of the connecting rod is rotationally connected with the shifting fork, and the other end of the connecting rod is connected with the other end of the mandrel and can drive the mandrel to rotate;

the shaft head of the angle sensor is fixed at the top end of the mandrel;

when the synchronous automatic clutch is in a disengaging or engaging state, the large-stroke measuring ring moves to drive the shaft head to rotate through the connecting rod, and the angle sensor measures the rotation angle according to the rotation of the shaft head;

further comprises:

a flange plate mounted on the housing;

the shaft sleeve is in interference connection with the flange plate;

the blanking cover is fixed on the flange plate;

the shaft sleeve is arranged outside the mandrel in a sealing manner, an annular cavity is formed between the shaft sleeve and the mandrel, the top end of the mandrel penetrates out of the flange plate to be positioned above the flange plate, and the blocking cover is arranged outside the top end of the mandrel in a sealing manner;

further comprises:

one end of the oil inlet pipe is communicated with the annular cavity, and the other end of the oil inlet pipe is communicated with an oil inlet joint outside the flange plate;

lubricating oil in the oil inlet pipe lubricates the mandrel through the annular cavity;

the mandrel is provided with a first radial hole I, a second radial hole II and a first axial hole which are communicated with each other;

a long hole is formed in the connecting rod;

a second radial hole and a second axial hole which are mutually communicated are formed in the shifting fork, and a ring groove communicated with the second radial hole is formed in a rotating shaft of the shifting fork;

two ends of the long hole are respectively communicated with the first radial hole II and the annular groove;

the oil distributing hole and the friction surface oil spraying hole are formed in the shifting fork, and the lubricating oil is sprayed out of the oil distributing hole and the friction surface oil spraying hole to lubricate the shifting fork and the friction surface between the shifting fork and the large-stroke measuring ring;

a cavity is formed in the blanking cover;

the shaft sleeve is provided with a drain hole for draining the lubricating oil leaked into the cavity;

the axis of the mandrel is parallel to and not coincident with the axis of the shifting fork, and meanwhile, the axis of the mandrel and the axis of the shifting fork are perpendicular to the rotation axis space of the synchronous automatic clutch.