CN208968749U - A kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism - Google Patents
A kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism Download PDFInfo
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- CN208968749U CN208968749U CN201821664542.9U CN201821664542U CN208968749U CN 208968749 U CN208968749 U CN 208968749U CN 201821664542 U CN201821664542 U CN 201821664542U CN 208968749 U CN208968749 U CN 208968749U
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Abstract
This patent provides a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism, including the 2 groups of differential regulating mechanisms, 2 groups of axial force transducers, 2 groups of mechanical seals to be measured, left and right adjusting nut, seal cavity being set on axle sleeve;Differential regulating mechanism is made of differential swivel nut, the stationary ring holding nut of outer marginal zone feather key, seal chamber end cap;Stationary ring holding nut of two sections of screw threads respectively with seal chamber end cap, outer marginal zone feather key screws on differential swivel nut;When rotational difference movable snail sleeve, realize that contact pressure F t real-time and precise in dynamic and static ring end face is adjusted;Dynamic and static ring end face contact pressure F t is axial force transducer stress Fc, the pressure medium in stationary ring O-ring frictional force Fo, seal chamber acts on the algebraical sum of the axial force F y on stationary ring net area;When differential swivel nut forward direction promotes, dynamic and static ring end face contact pressure F t=Fc-Fo+Fy;When differential swivel nut is reversely retracted, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
Description
Technical field
This patent belongs to end face seal observation and control technology field, more particularly to one kind towards mechanical sealing performance tester
Dynamic and static ring end face contact pressure real-time and precise regulating mechanism.
Background technique
Mechanical seal is mostly used for the axial seal of the power input shaft of equipment such as pump, blender and compressor, petroleum,
The wide range of areas such as chemical industry, electric power, aviation have application.In mechanical seal test device, the size of contact pressure between dynamic and static ring
There is very close relationship with the performance of mechanical seal.Contact pressure is too small, seals and is easy failure;Contact pressure is too big, rubs
Wiping torque will also become larger, to influence the rotation of axis and unstable wear dynamic and static ring.So the tune of dynamic and static ring end face contact pressure
Section and measurement are extremely important part in mechanical seal test device.
In currently known face seals and experimental rig, the machinery that can adjust contact pressure between dynamic and static ring is close
Sealing property experimental rig is not very much, wherein more advanced device such as 103267613 A of patent CN, uses working-spindle
Across the axle sleeve of clearance fit therewith, it is equal to be arranged screw pitch in the middle part of axle sleeve, two sections of opposite screw threads of hand of helix, respectively with
Left nut and right nut screw, and open up the short pin hole parallel with axle sleeve axis on left nut and right nut, for being inserted into short pin, prevent
Only two nuts relatively rotate, and rotary shaft drives left and right nut equidistant to the left, move right, and push respectively with left nut and right
Two groups of rotating seats of nut contact push two groups of rotating rings to the compression of stationary ring by two groups of springs and two groups of throw-out collars.The single-cantilever
The equivalent that structure realizes two groups of mechanical seal spring pressures is adjusted, and is overcome caused by sealing resonator end surface immersion liquid area does not wait not
Balancing axial thrust.Although this patent has many advantages, there is also some disadvantages, can not such as adjust in real time when testing and carrying out
Spring pressure is saved, the spring pressure of adjusting is also empirical adjusting, can not be accurate to specific value.
This patent aiming at 103267613 A of patent CN shortcoming, towards mechanical sealing performance tester
The dynamic and static ring end face contact pressure real-time and precise regulating mechanism of design.
Summary of the invention
This technology is to solve dynamic and static ring end face contact pressure in existing machinery sealing property tester and cannot adjust in real time
The problems such as section, poor accuracy, low reliability, provides a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism.For
Other kinds of mechanical sealing performance tester, the innovation that can also use for reference this patent are changed recycling.
To achieve the above object, contact pressure real-time and precise regulating mechanism in dynamic and static ring end face described in this patent, including wear
It is placed on axle sleeve 15 and about 2 groups of differential regulating mechanisms, 2 groups of axial force transducers, the 2 groups of machines to be measured being arranged symmetrically in the middle part of axle sleeve
Tool sealing, left and right adjusting nut 14 and seal cavity 18;Different, the identical thread helix of screw pitch with rotation direction of left and right adjusting nut 14
It is connected in the middle part of axle sleeve;Axle sleeve 15 is set on main shaft 1, axial without positioning, the circumferential torsion force measurement component 2 by being connected in main shaft
Positioning;The mechanical seal to be measured by stationary ring O-ring 8, stationary ring 19, rotating ring 10, rotating ring O-ring 11, rotating seat 17, spring 12,
Spring base 13 forms;
The differential regulating mechanism is by differential swivel nut 4, the stationary ring holding nut 5 of outer marginal zone feather key, 6 groups of seal chamber end cap
At;Left and right seal chamber end cap 6 is fixed on 18 both ends of seal cavity, two sections of screw threads on differential swivel nut 4 respectively with seal chamber end cap
6, stationary ring holding nut 5 screws;It is opened up in the interior circular hole side of seal chamber end cap 6 and guarantees leading for the axial movement of stationary ring holding nut 5
To keyway;2 groups of differential regulating mechanisms constitute seal chamber with seal cavity 18 and axle sleeve 15 together, and left and right stationary ring holding nut 5 divides
Not Tong Guo axial force transducer 7 accept 9 end of stationary ring of arranged on left and right sides mechanical seal to be measured, arranged on left and right sides machinery to be measured is close
9 external cylindrical surface of stationary ring of envelope is coupled with the inner cylinder face of left and right seal chamber end cap 6 using seal with O ring respectively;
When rotational difference movable snail sleeve 4, differential swivel nut 4 is axially promoted or is retracted relative to seal chamber end cap 6, stationary ring holding nut
5 retract axially downwards or promote in leading for its outer rim feather key, so that stationary ring holding nut 5 compresses rotating ring 10 with dynamic and static ring 9, or
It pushes outside stationary ring 9 and moves under the effect of 12 power of spring, cooperation is placed in the sensing of the axial force between stationary ring holding nut 5 and stationary ring 9
Device 7 realizes that contact pressure F t real-time and precise in dynamic and static ring end face is adjusted;
The dynamic and static ring end face contact pressure F t is axial force transducer stress Fc, stationary ring O-ring frictional force Fo, seal chamber
Interior pressure medium acts on the algebraical sum of the axial force F y on stationary ring net area;When differential 4 positive propulsion of swivel nut, dynamic and static ring end
Surface contact pressure Ft=Fc-Fo+Fy;When differential swivel nut 4 is reversely retracted, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
Above-mentioned dynamic and static ring end face contact pressure real-time and precise regulating mechanism, different, the identical screw thread spiral shell of screw pitch with rotation direction
Rotation is connected in the preconditioning that the left and right adjusting nut 14 in the middle part of axle sleeve carries out dynamic and static ring end face contact pressure, with differential regulating mechanism
Realize that the real-time and precise of dynamic and static ring end face contact pressure is adjusted.Dynamic and static ring end face before differential differential tuning section can be guaranteed by carrying out preconditioning
Contact pressure is rapidly achieved preset range, reduces the regulated quantity of dynamic and static ring end face contact load, improves and adjusts efficiency.
Above-mentioned dynamic and static ring end face contact pressure real-time and precise regulating mechanism, two sections of thread pitch on differential swivel nut 4
Respectively L1 and L2, differential swivel nut 4 rotate a circle, and when two sections of hand of thread spiral are identical, stationary ring holding nut 5 is promoted at a slow speed
Or it retracts, mobile distance P1=L1-L2.It is slow due to being threaded in or out screw thread, adjust the variation of dynamic and static ring end face contact pressure
It measures small, ensure that load or unload process is steady, load or unload load is accurate.It is quiet when two sections of hand of thread spiral are opposite
Ring holding nut 5 is quickly propelled or is retracted, mobile distance P2=L1+L2;It can cause sound when due to being threaded in or out screw thread
The very fast load of ring contact face or quick separating, are conducive to the operating condition for simulating mechanical seal by instantaneous excitation.
Above-mentioned dynamic and static ring end face contact pressure real-time and precise regulating mechanism, it is quiet when differential gear adjusts spinning in and out
The frictional force of ring O-ring 8 is contrary with differential 4 spinning in and out of swivel nut;O-ring frictional force Fo can use following mechanism and side
Method measures: with one and the measurement hollow shaft 19 of the same diameter of stationary ring O-ring 8 of installation, setting the O of O-ring 8 in its both ends open
Shape ring recess;Measurement hollow shaft 19 passes through the seal cavity 18 that both ends are connected with seal chamber end cap 6, measures hollow shaft 19 and seal chamber
It is sealed between the inner hole of end cap 6 with O-ring;In formation such as seal cavity 18, measurement hollow shaft 19, seal chamber end caps 6
The medium of certain pressure is filled in seal chamber, to simulate the frictional force of the O-ring substantially identical with mechanical seal working condition
Force of sliding friction when feature, i.e. different medium pressure lower O-shape ring are with different distortion, measuring mechanism, as shown in Figure 9.It surveys
Amount 19 one end of hollow shaft directly adds load Q, and the other end places an axial force transducer 24, and axial force transducer 24 is supported on bullet
Property bearing 20 on.Compare the power Q of the power Fc that force snesor 24 measures and the load of measurement 19 shaft end of hollow shaft, difference is exactly two
The frictional force of O-ring, then the frictional force Fo of single O-ring=(Q-Fc)/2.
Above-mentioned dynamic and static ring end face contact pressure real-time and precise regulating mechanism is turned round force measurement component 2 and is arranged on axis 1,
Upper end passes through obround opening on axle sleeve 15, the torque between transmission axle 1 and axle sleeve 15;Turning round force measurement component 2 includes dynamometry spiral shell
Bolt 21, circumferential force snesor 22 and rolls set 23,21 upper end of dynamometry bolt are equipped with rolls set, it is possible to reduce axis 1 and axle sleeve 15 it
Between it is axially opposing mobile when friction;It is provided between dynamometry bolt 21 and rolls set between detection axis 1 and axle sleeve 15
The circumferential force snesor 22 of peripheral force.
Above-mentioned dynamic and static ring end face contact pressure real-time and precise regulating mechanism, at 15 both ends of axle sleeve apart from the same distance in end face
External cylindrical surface on be respectively set and be distributed in 4 circumferential through-holes being made of screw hole-unthreaded hole, put in the unthreaded hole close to main shaft
Ball 3 is set, is blocked in outside diameter silk plug 31, guarantees that the friction between axis 1 and axle sleeve 15 is rolling friction, reduces axis 1 and axis
Frictional force when set 15 is moved to axial and circumferentially rotated.
This patent the utility model has the advantages that
In this experimental rig, dynamic and static ring end face contact pressure regulating mechanism is symmetrically installed in shell two sides, rotates differential spiral shell
The axial position of 4 adjustable stationary ring holding nuts 5 is covered, and then carries out the adjusting of end force between rotating ring and stationary ring.It is differential
When the positive propulsion of swivel nut 4 (differential swivel nut, stationary ring holding nut, stationary ring, rotating ring are mobile to the middle part of axle sleeve), dynamic and static ring end face is connect
Touch pressure Ft=Fc-Fo+Fy;Differential swivel nut 4 reversely retracts that (differential swivel nut, stationary ring holding nut, stationary ring, rotating ring are to axle sleeve
When both ends are mobile, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
In view of axial force transducer stress Fc is measured in real time, stationary ring O-ring frictional force Fo is measured by testing, in seal chamber
The axial force F y that acts on stationary ring net area of pressure medium can be calculated, then dynamic and static ring end face contact pressure F t can root
It is calculated according to above-mentioned formula.
(1) present apparatus is combined using differential regulating mechanism with force snesor, and is aided with dependency structure, realizes dynamic and static ring
The real-time accurate adjusting of end face contact pressure.
(2) present apparatus mechanical seal test during measure and adjust dynamic and static ring end face contact load when without shut down,
Dismantle seal chamber;
(3) present apparatus uses circumferentially positioned, the free axis of axial movement and axle sleeve type of attachment, and on axle sleeve
2 groups of mechanical seals to be measured, 2 groups of differential regulating mechanisms, 2 groups of axial force transducers, left and right adjusting nut are symmetrical arragement construction,
So that installation is very convenient, only need that differential regulating mechanism, axial force transducer, mechanical seal to be measured, a left side will be set in order
The axle sleeve of right adjusting nut is put into seal chamber, without adjusting position of the mechanical seal to be measured in seal chamber, so that it may carry out machine
Tool seals the adjusting and measurement of dynamic and static ring end face contact load.
(4) present apparatus uses the differential regulating mechanism with identical rotation direction screw thread, and it is micro- that progress is slowly threaded in or out screw thread
Amount adjusts dynamic and static ring end face contact pressure, ensure that load or unload process is steady, load or unload load is accurate.
(5) present apparatus uses the differential regulating mechanism with oppositely oriented screw thread, forms sound when being threaded in or out screw thread
The very fast load of ring contact face or quick separating, are conducive to the operating condition for simulating mechanical seal by instantaneous excitation.
(6) present apparatus use preconditioning mechanism of the left and right adjusting nut as dynamic and static ring end face contact pressure, can into
Guarantee that contact pressure is rapidly achieved preset range before row differential differential tuning section, reduces what dynamic and static ring end face contact load was accurately adjusted
Regulated quantity improves adjusting efficiency.
Detailed description of the invention
Fig. 1 is a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism X-Y scheme;
Fig. 2 is the two-dimentional enlarged drawing that Fig. 1 device left and right sides dynamic and static ring end face contact pressure adjusts side;
Fig. 3 is Fig. 1 axis, axle sleeve, dynamometry bolt, rolls set, the position shape matching relationship schematic diagram between slotted hole
Fig. 4 is that torsion measures component diagram in Fig. 1 device;
Fig. 5 is frictional force, pressure medium and the axial force transducer stress of stationary ring O-ring when differential swivel nut promotes in Fig. 1
Situation;
Fig. 6 is frictional force, pressure medium and the axial force transducer stress of stationary ring O-ring when differential swivel nut retracts in Fig. 1
Situation;
Fig. 7 is the Principles of Regulation figure (reset condition) when Fig. 2 adjusting side mould intends slow-motion;
Fig. 8 is the Principles of Regulation figure (state after adjusting) when Fig. 2 adjusting side mould intends slow-motion;
Fig. 9 is stationary ring O-ring friction testing method schematic diagram;
Figure 10 is the schematic enlarged-scale views such as ball, silk plug.
Description of symbols:
Main shaft 1, turn round force measurement component 2, dynamometry bolt 21, circumferential force snesor 22, rolls set 23, ball 3, silk plug 31,
It is differential swivel nut 4, the stationary ring holding nut 5 of outer marginal zone feather key, seal chamber end cap 6, axial force transducer 7, stationary ring O-ring 8, quiet
Ring 9, rotating ring O-ring 11, spring 12, spring base 13, left and right adjusting nut 14, axle sleeve 15, conducting wire fairlead 16, moves rotating ring 10
Ring seat 17, seal cavity 18, measurement hollow shaft 19, elastic bearing 20, axial force transducer 24, stop pin 25.
Specific embodiment
In order to illustrate more clearly of this patent example or technical solution in the prior art, below by embodiment or existing skill
The required attached drawing used is briefly described in art description, it is clear that, drawings discussed below is only this patent
Some embodiments for those of ordinary skill in the art without any creative labor, can be with root
Other accompanying drawings are obtained according to these attached drawings.
Fig. 1 is a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism X-Y scheme, including main shaft 1, torsion measure
Component 2, ball 3, differential swivel nut 4, the stationary ring holding nut 5 of outer marginal zone feather key, seal chamber end cap 6, axial force transducer 7,
Left and right adjusting nut 14, axle sleeve 15, conducting wire fairlead 16, rotating seat 17, seal cavity 18, dynamometry bolt 21, peripheral force sensing
Device 22, rolls set 23, silk plug 31, wherein 2 sets of mechanical seals to be measured respectively include stationary ring O-ring 8, stationary ring 9, rotating ring 10, rotating ring O
Shape circle 11, spring 12, spring base 13.
Fig. 2 is the two-dimentional enlarged drawing that Fig. 1 device left and right sides dynamic and static ring end face contact pressure adjusts side.
Fig. 3 is Fig. 1 axis 1, axle sleeve 15, dynamometry bolt 21, rolls set 23, the position shape matching relationship between slotted hole
Schematic diagram.This structure can be when axis 1 and axle sleeve 15 be using dynamometry bolt transmitting torque, and axis 1 can be moved axially with axle sleeve 15,
It is circumferentially fixed.
Fig. 4 is that 2 schematic diagram of force measurement component is turned round in Fig. 1 device.23 sets of rolls set on dynamometry bolt 21, rolls set 23
Internal diameter and 21 head outer diameter of dynamometry bolt are clearance fit, it is therefore an objective to reduce frictional force when rolling, rolls set 23 and dynamometry spiral shell
There is circumferential force snesor 22 between bolt 21.
Fig. 5 is frictional force, pressure medium and the axial force transducer stress of stationary ring O-ring when differential swivel nut promotes in Fig. 1
Situation.When differential swivel nut 4 promotes (differential swivel nut 4, stationary ring 9 etc. are mobile to axle sleeve centre), the 7 stress side Fc of axial force transducer
To identical as direction of propulsion, 8 direction frictional force Fo of stationary ring O-ring and direction of propulsion are on the contrary, the direction pressure medium Fy and propulsion side
To identical, dynamic and static ring end face contact pressure F t=Fc-Fo+Fy.
Fig. 6 is frictional force, pressure medium and the axial force transducer stress of stationary ring O-ring when differential swivel nut retracts in Fig. 1
Situation.When differential swivel nut 4 retracts (differential swivel nut 4, stationary ring 9 etc. are mobile to axle sleeve both ends), the 7 stress side Fc of axial force transducer
To with retract it is contrary, 8 direction frictional force Fo of stationary ring O-ring with retract contrary, the direction pressure medium Fy and the side of retracting
To on the contrary, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
Fig. 7 is the Principles of Regulation figure (reset condition) when Fig. 2 adjusting side mould intends slow-motion, and a is reset condition.Fig. 8 is Fig. 2 tune
The Principles of Regulation figure (state after adjusting) when side form intends slow-motion is saved, b is state after adjusting.Slow-motion time difference movable snail sleeve 4 and seal chamber
End cap 6 and 5 threaded engagement of stationary ring holding nut and be right-hand screw.If being supported on differential swivel nut 4 with seal chamber end cap 6 and stationary ring
The screw pitch that nut 5 screws is respectively L1=5mm, L2=4mm, differential swivel nut 4 with dynamic and static ring holding nut 5 clockwise or counter-clockwise
When rotating a circle, stationary ring holding nut 5 is slow forward (i.e. differential swivel nut 4, stationary ring 9 are mobile to the middle part of axle sleeve, are to the left in figure)
The mobile distance P1=L1-L2=1mm of speed.Distance of the stationary ring left end relative to 6 right end of seal chamber end cap, from the L(before adjusting referring to
Fig. 7), the L+P1(after adjusting is changed into referring to Fig. 8).
Fig. 9 is stationary ring O-ring friction testing method schematic diagram.With one and the same diameter of stationary ring O-ring 8 of installation
Hollow shaft 19 is measured, offers O-ring slot at its both ends.Load Q is directly added in one end of measurement hollow shaft 19, the other end is put
An axial force transducer 24 is set, axial force transducer 24 is supported on elastic bearing 20.Compare power Fc that force snesor measures and
Measure 19 shaft end of hollow shaft load power Q, difference is exactly the frictional force of two O-rings, then the frictional force Fo of single O-ring=
(Q-Fc)/2。
When specific test group installs standby, first the stationary ring holding nut 5 of one group of differential swivel nut 4 and outer marginal zone feather key is packed into
The seal chamber end cap 6 of side sticks axial force transducer 7 in the place that stationary ring holding nut 5 is contacted with stationary ring 9;The other side
Regulating mechanism assembles in the same way.
Mechanical sealing assembly and ball are installed on axle sleeve again: left and right adjusting nut 14 being screwed in into axle sleeve 15 on axle sleeve 15
Intermediate thread position, then by stop pin 25 be inserted into left and right adjusting nut 14 in, then by spring base 13, spring 12, rotating seat 17,
Rotating ring O-ring 11, rotating ring 10, stationary ring 9 and stationary ring O-ring 8 are successively symmetrically mounted on the two sides of left and right adjusting nut, in axle sleeve 15
Ball 3 is loaded onto upper corresponding hole, and screws in silk plug 31(referring to Fig. 1, Figure 10).
Finally carry out integral installation: the differential regulating mechanism that side has been installed is attached to seal cavity close to the one of motor
Side, then the axle sleeve for installing mechanical sealing assembly and ball is set on axis, finally filled in the seal cavity side far from motor
Upper differential regulating mechanism screws in torsion in main shaft two side holes and measures component 2, completes assembly.
In this experimental rig, the mounting structure of two sets of mechanical seal is similar with the structure in 103267613 A of patent CN.
Two sets of mechanical seals all are symmetrically installed using the left and right adjusting nut two sides of the installation at 15 center of axle sleeve, wherein two sets mechanical close
Envelope respectively include stationary ring O-ring 8, stationary ring 19, rotating ring 10, rotating ring O-ring 11, rotating seat 17, spring 12, spring base 13, difference
Be in patent CN 103267613 A described device, using adjust left and right adjusting nut it is opposite close to or separation reduce
Or increase dynamic and static ring end face contact pressure;And this patent, use symmetrical two groups of bands axial force instead at the end cap of seal cavity two sides
Axial force transducer 7 is arranged in the differential regulating mechanism of sensor 7 between stationary ring holding nut 5 and stationary ring 9, different with rotation direction,
The identical thread helix of screw pitch is connected in the left and right adjusting nut 14 in the middle part of axle sleeve and carries out the presetting of dynamic and static ring end face contact pressure
Section, dynamic and static ring end face contact pressure rapidly enters preset range before guaranteeing differential differential tuning section, reduces the contact of dynamic and static ring end face and carries
The regulated quantity that lotus is accurately adjusted improves adjusting efficiency.
In this experimental rig, dynamic and static ring end face contact pressure regulating mechanism is symmetrically installed in shell two sides, utilizes sealing
Chamber end cap 6 supports the adjusting of differential swivel nut 4 with the progress end force of stationary ring holding nut 5;Screw pitch on differential swivel nut 4, and it is close
The screw pitch that envelope chamber end cap 6 screws is big, and the screw pitch screwed with stationary ring holding nut 5 is small.Two sections of thread pitch on differential swivel nut 4
Respectively L1 and L2, differential swivel nut 4 rotate a circle, and when two sections of hand of thread spiral are identical, stationary ring holding nut 5 is promoted at a slow speed
Or it retracts, mobile distance P1=L1-L2;It is slow due to being threaded in or out screw thread, adjust the variation of dynamic and static ring end face contact pressure
It measures small, ensure that load or unload process is steady, load or unload load is accurate.It is quiet when two sections of hand of thread spiral are opposite
Ring holding nut 5 is quickly propelled or is retracted, mobile distance P2=L1+L2;It can cause sound when due to being threaded in or out screw thread
The very fast load of ring contact face or quick separating, are conducive to the operating condition for simulating mechanical seal by instantaneous excitation.
In this experimental rig, axial force transducer 7 is mounted between stationary ring and stationary ring holding nut, sticks on stationary ring support
On nut.The dynamic and static ring end face contact pressure F t is force acting on transducer Fc, stationary ring O-ring frictional force Fo, pressure medium act on
The algebraical sum of axial force F y on stationary ring net area;When differential 4 positive propulsion of swivel nut, dynamic and static ring end face contact pressure F t=Fc-
Fo+Fy;When differential swivel nut 4 is reversely retracted, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
In this experimental rig, dynamometry bolt 21 and 1 aperture of axis cooperate, and pass through obround opening transmission axle 1 and axis on axle sleeve
Torque between set 15;Rolls set 23 is housed on the outside of dynamometry bolt 21, it is possible to reduce when being moved axially between axis 1 and axle sleeve 15
Friction.
The dynamometry bolt with rolls set 23 in this experimental rig, using the oblong hole opened on axle sleeve, on main shaft 1
21 cooperate with obround opening, and axis and axle sleeve may be implemented and move axially, is circumferentially fixed, in addition symmetrical configuration in shell, can be with
It realizes when adjusting dynamic and static ring end face contact pressure in real time, the dynamic and static ring end face on 12 autobalance both sides of spring contacts pressure
Power, and greatly reduce resistance when adjusting there is no very big additional agents pressure when adjusting.
In this experimental rig, measurement for end face friction torque can use and turn round force measurement component 2 and measure at axle sleeve
Peripheral force, the peripheral force recycled obtain the end face friction that torque herein is dynamic and static ring multiplied by radius herein and turn round
Square.The method realizes the precise measurement of mechanical seal end surface fretting wear torque.2 groups of mechanical seals are mounted on clearance fit
In on the axle sleeve of main shaft, end face frictional wear torque passes to setting by axle sleeve milli without loss and is located at axle sleeve two on main shaft
The torsion force measurement component 2 in oblong openings is held, ensure that the accuracy of mechanical seal face friction torque measurement.
In this experimental rig, beaker can be placed at 6 leakage of seal chamber end cap, hold by measurement for leakage rate
Leakage liquid is weighed again.
In this experimental rig, seal face temperature can bore 6 phase differences at 9 back uniform diameters of stationary ring as 60 °, depth
The not equal hole of degree, and sensor of immersioning thermocouple in hole measures.To measure apart from seal face h1, h2, h3, h4,
Temperature value t at h5 and h6, is fitted to temperature t and distance h equation t=t (h), by calculating temperature when h=0, can be obtained machine
Tool seal face temperature.
In this experimental rig, face pressure identical mechanical seal identical using 2 packet sizes is tested together, using 2 groups of machines
Tool sealing accumulates the average value of leakage rate to characterize the leakage rate of single group mechanical seal, is rubbed using 2 groups of mechanical seals accumulation end faces
End face friction torque of the average value of torque as single group mechanical seal is wiped, reducing randomness influences measurement bring.
Claims (5)
1. a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism, including be set on axle sleeve (15) and about in axle sleeve
2 groups of differential regulating mechanisms that portion is arranged symmetrically, 2 groups of axial force transducers, 2 groups of mechanical seals to be measured, left and right adjusting nut (14),
Seal cavity (18);With rotation direction, different, the identical thread helix of screw pitch is connected in the middle part of axle sleeve left and right adjusting nut (14);Axle sleeve
(15) it is set on main shaft (1), axial without positioning, the circumferential torsion force measurement component (2) by being connected in main shaft positions;It is described to be measured
Mechanical seal is by stationary ring O-ring (8), stationary ring (9), rotating ring (10), rotating ring O-ring (11), spring (12), spring base (13), dynamic
Ring seat (17) composition;It is characterized by:
The differential regulating mechanism is by differential swivel nut (4), the stationary ring holding nut (5) of outer marginal zone feather key, seal chamber end cap (6)
Composition;Left and right seal chamber end cap (6) is fixed on seal cavity (18) both ends, two sections of screw threads on differential swivel nut (4) respectively with it is close
Seal chamber end cap (6), the stationary ring holding nut (5) of outer marginal zone feather key screws;Guarantor is opened up in the interior circular hole side of seal chamber end cap (6)
Demonstrate,prove the guide key groove of stationary ring holding nut (5) axial movement;2 groups of differential regulating mechanisms and seal cavity (18) and axle sleeve (15)
Seal chamber is constituted together, and it is to be measured that left and right stationary ring holding nut (5) accepts arranged on left and right sides by axial force transducer (7) respectively
Stationary ring (9) end of mechanical seal, stationary ring (9) external cylindrical surface of arranged on left and right sides mechanical seal to be measured respectively with left and right seal chamber
The inner cylinder face of end cap (6) is coupled using seal with O ring;
When rotational difference movable snail sleeve (4), differential swivel nut (4) axially promotes or retracts relative to seal chamber end cap (6), and stationary ring supports spiral shell
Female (5) are retracted axially downwards or are promoted in leading for its outer rim feather key, so that stationary ring holding nut (5) band dynamic and static ring (9) compresses
Rotating ring (10), or push stationary ring (9) to move outside under the effect of spring (12) power, cooperation is placed in stationary ring holding nut (5) and stationary ring
(9) axial force transducer (7) between realizes that contact pressure F t real-time and precise in dynamic and static ring end face is adjusted;
The dynamic and static ring end face contact pressure F t is axial force transducer stress Fc, in stationary ring O-ring frictional force Fo, seal chamber
Pressure medium acts on the algebraical sum of the axial force F y on stationary ring net area;When differential swivel nut (4) forward direction promotes, dynamic and static ring end face
Contact pressure F t=Fc-Fo+Fy;When differential swivel nut (4) is reversely retracted, dynamic and static ring end face contact pressure F t=Fc+Fo+Fy.
2. a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism according to claim 1, it is characterised in that: with
Rotation direction is different, the identical thread helix of screw pitch is connected in the left and right adjusting nut (14) in the middle part of axle sleeve and carries out the contact of dynamic and static ring end face
The preconditioning of pressure realizes that the real-time and precise of dynamic and static ring end face contact pressure is adjusted with differential regulating mechanism.
3. a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism according to claim 1, it is characterised in that: poor
Two sections of thread pitch are respectively L1 and L2 on movable snail sleeve (4), and differential swivel nut (4) rotates a circle, when two sections of thread helix sides
To it is identical when, stationary ring holding nut (5) is promoted or is retracted at a slow speed, mobile distance P1=L1-L2.
4. a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism according to claim 1, it is characterised in that: turn round
Force measurement component (2) is arranged on axis (1), and the upper end passes through obround opening transmission axle (1) and axle sleeve (15) on axle sleeve (15)
Between torque;Turning round force measurement component (2) includes dynamometry bolt (21), circumferential force snesor (22) and rolls set (23), dynamometry
Bolt (21) upper end is equipped with rolls set, it is possible to reduce friction when axially opposing mobile between axis (1) and axle sleeve (15);In dynamometry
The circumferential force snesor for peripheral force between detection axis (1) and axle sleeve (15) is provided between bolt (21) and rolls set (23)
(22).
5. a kind of dynamic and static ring end face contact pressure real-time and precise regulating mechanism according to claim 1, it is characterised in that:
Axle sleeve (15) both ends are respectively set on the external cylindrical surface apart from the same distance in end face is distributed in circumferential 4 by screw hole-unthreaded hole group
At through-hole, place ball (3) in the unthreaded hole close to main shaft, blocked in outside diameter with silk plug (31), guarantee axis (1) and axle sleeve
(15) friction between is rolling friction, reduces frictional force when axis (1) and axle sleeve (15) moves to axial and circumferentially rotates.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110701112A (en) * | 2019-10-31 | 2020-01-17 | 今麦郎面品有限公司 | Pump for food industry |
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2018
- 2018-10-14 CN CN201821664542.9U patent/CN208968749U/en not_active Withdrawn - After Issue
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110701112A (en) * | 2019-10-31 | 2020-01-17 | 今麦郎面品有限公司 | Pump for food industry |
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