JP6795412B2 - mechanical seal - Google Patents

Description

The present invention relates to a mechanical seal that seals a shaft seal formed between a housing of a pump, a stirrer, or the like and a rotating shaft.

In the conventional mechanical seal, one end of a cylindrical bellows outerly fitted to the rotating shaft is fixed to the rotating shaft from the outer diameter side by an annular clamp, and the sliding surface and housing of the rotating sealing ring provided at the other end of the bellows. By sliding the sliding surface of the static sealing ring fixed to the above, the shaft sealing portion formed between the housing and the rotating shaft is sealed. Specifically, the rotary sealing ring of the bellows is fitted with an annular retainer, and the annular clamp is provided with a drive pin extending in the axial direction. The retainer can rotate together with the rotating shaft by inserting a drive pin into a recess that is recessed from the outer peripheral surface to the inner diameter side at one end of the retainer (the end on the annular clamp side) and is opened to the one end side in the axial direction. Further, by providing a spring for urging in the axial direction between the retainer and the annular clamp, the rotary sealing ring of the bellows held by the retainer and the static sealing ring fixed to the housing are in contact with each other. It is maintained and the sealing performance between sliding surfaces is enhanced (see Patent Document 1).

In such a mechanical seal, the retainer is externally fitted to the rotary sealing ring of the bellows and is connected by a drive pin and a spring so as to be relatively movable in the radial and axial directions with respect to the annular clamp. The rotary sealing ring side receives centrifugal force, self-excited vibration, etc. and moves relative to the static sealing ring in the radial direction, and a precession motion may occur on the sliding surface to deteriorate the sealing performance.

In the mechanical seal disclosed in Patent Document 1, an annular vibration damping body, which is screwed directly to the rotating shaft while being fitted on the outer peripheral surface of the rotating shaft, has an annular clamp and a retainer having an outer diameter. It extends in the axial direction so as to cover from the side, and is in contact with the outer peripheral surface of the retainer via an O-ring provided on the inner surface side of the vibration damping body. That is, since the retainer can be held from the outer diameter side by the vibration damping body directly fixed to the rotating shaft and the relative movement of the rotating sealing ring with respect to the static sealing ring in the radial direction can be suppressed, the precession on the sliding surface can be suppressed. The occurrence of movement is suppressed and the sealing performance is improved.

Japanese Unexamined Patent Publication No. 2012-26509 (page 5, FIG. 1)

However, in Patent Document 1, the retainer is held by a vibration damping body extending from a position axially away from the sliding surface from the annular clamp, and is axially separated from the annular clamp. Since the drive pin and the spring are connected so as to be relatively movable in the radial direction and the axial direction, there is a problem that the axis of the retainer is easily displaced with respect to the annular clamp, and the assembly accuracy of the retainer is lowered.

The present invention has been made in view of such problems, and an object of the present invention is to provide a mechanical seal having high retainer assembly accuracy.

In order to solve the above problems, the mechanical seal of the present invention is used.
With a static sealing ring,
A bellows having a rotary sealing portion that slides relative to the static sealing ring in response to the rotation of the rotating shaft and a base end portion provided on the side opposite to the rotary sealing portion in the axial direction.
A retainer that holds the rotary seal portion from the radial direction,
A fixing / vibration damping member that fixes the base end portion to the rotary shaft side member and is loosely fitted to the retainer in the radial direction.
A spring that urges the static sealing ring and the rotary sealing portion in the axial direction so as to bring them close to each other.
It is characterized in that it is provided with an elastic member provided between the retainer and the fixing / damping member at a portion where the retainer and the fixing / damping member are loosely fitted.
According to this feature, the retainer is loosely fitted in the radial direction to the fixed / damping member having high assembly accuracy with respect to the rotating shaft, and the elastic member provided between the retainer and the fixed / damping member is deformed. , The relative movement of the retainer with respect to the fixing / damping member in the radial direction is suppressed, and the axis of the retainer is easily held in a state of being aligned with the axis of the fixing / damping member, and the assembly accuracy of the retainer is improved. Can be enhanced.

The fixing / damping member is characterized in that it is loosely fitted on the inner diameter side of the retainer.
According to this feature, the assembling state of the retainer to the fixing / damping member can be confirmed from the outer diameter side, so that the assembling accuracy of the retainer can be improved. Further, since the fixing / damping member has a structure that is loosely fitted on the inner diameter side of the retainer, the length of the fixing / damping member extending in the axial direction can be shortened, and the assembly accuracy of the retainer can be improved. Can be done.

The fixing / damping member is characterized in that a protruding portion protruding toward the outer diameter side is provided.
According to this feature, a gap in the axial direction is formed by the retainer and the protruding portion protruding toward the outer diameter side of the fixing / damping member, and it is easy to check the assembled state of the retainer with respect to the fixing / damping member from the outer diameter side. Therefore, the assembly accuracy of the retainer can be further improved. Further, as a preferred embodiment, if the shape of the projecting portion is annular, an annular gap is formed between the retainer and the projecting portion projecting to the outer diameter side of the fixing / damping member, so that the retainer can be assembled. It will be easier to check.

A detent member for detenting the fixing / damping member and the retainer so that they do not rotate relative to each other is provided.
The fixing / damping member is loosely fitted with the retainer on the inner diameter side of the detent member.
According to this feature, the position of the detent member can be confirmed from the gap between the fixing / damping member formed on the outer diameter side of the retainer, so that the fixing / damping member and the retainer can be easily assembled. it can.

The fixing / vibration damping member includes a fixing member that fixes the base end portion to the rotating shaft and a vibration damping member that is loosely fitted with the retainer.
The fixing member and the vibration damping member are characterized in that they are provided separately.
According to this feature, the fixing / damping member can individually perform the work of loosely fitting the vibration damping member with the retainer and the work of fixing the base end portion of the bellows to the rotating shaft by the fixing member. Assembling workability can be improved.

The fixing member is a split clamp.
The vibration damping member is characterized in that it is an annular body.
According to this feature, after the damping member which is an annular body is inserted into the rotating shaft and loosely fitted with the retainer, the fixing member which is a split clamp is attached to the rotating shaft from the outer diameter side and integrated with the damping member. Since it can be fixed to, the accuracy of assembling the retainer to the fixing / damping member and the workability of assembling can be improved.

It is sectional drawing which shows the mechanical seal in an Example. It is sectional drawing which shows the state which the rotary sealing ring of a bellows moved relative to the static sealing ring in the radial direction.

A mode for carrying out the mechanical seal according to the present invention will be described below based on examples.

The mechanical seal according to the embodiment will be described with reference to FIGS. 1 and 2. Hereinafter, the left side of the paper surface of FIG. 1 will be described as the inside of the mechanical seal, and the right side of the paper surface of FIG. 1 will be described as the outside of the mechanical seal (atmosphere side).

As shown in FIG. 1, the mechanical seal 1 according to the present embodiment is used in the field of shaft sealing such as a pump and a stirrer, and a rotating shaft 3 inserted into a housing 2 and a shaft hole 20 provided in the housing 2. It is attached to seal between (shaft seal) and. The rotating shaft 3 is generally made of metal such as stainless steel, and the surface of the shaft may be coated. If the device for sealing the shaft is a pump, blades (not shown) are not shown inside the machine. The car is installed.

As shown in FIG. 1, the mechanical seal 1 includes a case 4 and a static sealing ring 5 fixed to the housing 2, a sleeve 6 (rotating shaft side member) assembled to the rotating shaft 3, a bellows 7, a retainer 8, and fixed. -It is mainly composed of a vibration damping member 9 and a set ring 10. For convenience of explanation, the cross-sectional view of the mechanical seal 1 shall show a cross-sectional view cut by two planes intersecting at the axial center. Further, for the member configured in an annular shape, the illustration of the end face is partially omitted.

First, the structures of the housing 2, the case 4 fixed to the housing 2, and the static sealing ring 5 will be described in detail.

As shown in FIG. 1, the housing 2 is formed with an annular protrusion 21 that projects from the peripheral edge of the opening of the shaft hole 20 toward the outside of the machine on the end surface 2a on the outside of the machine. The annular projecting portion 21 is fitted with the divided cases 23, 23 divided into two in the circumferential direction. The split cases 23 and 23 are integrally fastened with connecting metal fittings and bolts (not shown), and are fixed to the outer end surface 2a of the housing 2 with bolts (not shown) with the mechanical seal 1 covered from the outer diameter side in a sealed manner. Has been done.

Further, the housing 2 is formed with an annular convex portion 22 that protrudes from the inner circumference of the outer side of the machine to the inner diameter side of the annular protrusion 21. According to this, it is possible to prevent the static sealing ring 5 inserted into the shaft hole 20 from the inside of the machine by the annular convex portion 22 to come out to the outside of the machine. The structure of assembling the case 4 and the static sealing ring 5 to the shaft hole 20 of the housing 2 will be described in detail later.

The case 4 is provided with a shaft hole 40 through which the sleeve 6 is inserted, and has an annular shape. Further, the case 4 is formed with a flange 41 extending from the outer periphery of the inside of the machine toward the outer diameter side, and an annular protrusion 42 protruding from the outer diameter side of the end surface 4a on the outside of the machine toward the outside of the machine. ing.

The static sealing ring 5 is provided with a shaft hole 50 through which the sleeve 6 is inserted, and forms an annular shape. Further, the static sealing ring 5 is formed with an annular convex portion 51 extending from a substantially central portion in the axial direction of the outer circumference toward the outer diameter side. Further, the static sealing ring 5 is equipped with O-rings 101 and 102 having elasticity on the outer circumference of a portion having a diameter smaller than that of the annular convex portion 51 formed inside and outside the machine with respect to the annular convex portion 51, respectively. ..

The statically sealed ring 5 is made of SiC by a special conversion method (the carbon surface is partially made into SiC to reinforce the surface strength so that both the abrasion resistance of the SiC and the self-lubricating property of the carbon are combined). It is being manufactured. Further, it may be manufactured by other SiC such as diamond-coated SiC or reaction-sintered SiC (having a composition of SiC + Si).

Next, the structure of assembling the static sealing ring 5 and the case 4 to the shaft hole 20 of the housing 2 will be described in detail.

As shown in FIG. 1, the static sealing ring 5 is press-fitted into the shaft hole 20 of the housing 2 from the inside of the machine with the O-rings 101 and 102 mounted. At this time, the O-rings 101 and 102 are pressure-contacted between the outer circumference of the static sealing ring 5 and the inner circumference of the shaft hole 20 of the housing 2. Further, the case 4 is inserted into the shaft hole 20 of the housing 2 from the inside of the machine in a state where the static sealing ring 5 is press-fitted into the shaft hole 20 of the housing 2. The case 4 is fixed to the housing 2 by inserting bolts 43, 43, ... From the inside of the machine into a plurality of screw holes (not shown) provided in the flange 41.

At this time, in the case 4, the outer end surface 41a of the flange 41 is brought into contact with the inner end surface 2b of the housing 2, so that the housing 2 and the case 4 are accurately aligned in the axial direction. It has become.

Further, in a state where the housing 2 and the case 4 are aligned in the axial direction, the O-ring 101 mounted inside the machine of the static sealing ring 5 is the annular protrusion 42 of the case 4 and the static sealing ring 5. The O-ring 102 that is pressure-welded to the annular convex portion 51 and mounted on the outside of the static sealing ring 5 is pressure-welded to the annular convex portion 22 of the housing 2 and the annular convex portion 51 of the static sealing ring 5. ing. According to this, the gap between the inner circumference of the housing 2 and the outer circumference of the static sealing ring 5 can be sealed by the O-rings 101 and 102.

Further, the static sealing ring 5 is provided via an elastic O-rings 101 and 102 mounted between the annular protrusion 42 of the case 4 and the annular convex portion 22 of the housing 2 and the annular convex portion 51 of the static sealing ring 5. It is held in a state of being urged in the axial direction. At this time, the end surface 5b on the inside of the machine of the static sealing ring 5 and the end face 4a on the outside of the machine of the case 4 are separated from each other in the axial direction.

Next, the structure of the sleeve 6, the bellows 7, the retainer 8, the fixing / damping member 9, and the set ring 10 and the structure of assembling to the rotating shaft 3 will be described in detail.

As shown in FIG. 1, the sleeve 6 is provided with a shaft hole 60 through which the rotating shaft 3 is inserted, and has a tubular shape. The sleeve 6 is generally made of metal such as stainless steel, and is fixed to the rotating shaft 3 to rotate together with the rotating shaft 3.

Further, the outer circumference of the sleeve 6 is reduced in diameter from the outside of the machine to the inside of the machine, and the first outer peripheral surface 61 and the second outer peripheral surface 62 are formed in this order from the outside of the machine.

The bellows 7 is provided with a shaft hole 70 through which the sleeve 6 is inserted, and has a substantially cylindrical shape. The bellows 7 is a metal molded product or a resin molded product, and is fitted onto the first outer peripheral surface 61 of the sleeve 6.

Further, the bellows 7 has a base end portion 71 formed at one end (the end outside the machine), a rotary sealing ring 72 (rotary sealing portion) formed at the other end (the end inside the machine), and a base end portion. It is composed of a bellows portion 73 that connects the 71 and the rotary sealing ring 72 in the axial direction.

The base end portion 71 of the bellows 7 is formed in a cylindrical shape having an inner diameter substantially the same as the outer diameter of the first outer peripheral surface 61 of the sleeve 6, and abuts on the first outer peripheral surface 61 of the sleeve 6 in the circumferential direction. There is. Further, the base end portion 71 is formed with a flange 71a extending from the outer periphery of the machine to the outer diameter side.

The rotary sealing ring 72 of the bellows 7 is formed of an annular shape having an inner diameter larger than the outer diameter of the first outer peripheral surface 61 of the sleeve 6, and has a flange 74 extending from the outer circumference inside the machine toward the outer diameter side and the inside of the machine. An annular projecting portion 75 projecting from the end surface 72a of the machine toward the inside of the machine is formed. The end face of the annular protrusion 75 of the rotary sealing ring 72 on the inside of the machine is slid relative to the end face 5a on the outside of the machine of the static sealing ring 5 fixed to the housing 2 in a state of being substantially perpendicular to the axial direction. It is movable and forms a sliding surface S of the mechanical seal 1 together with the end surface 5a on the outer side of the machine of the static sealing ring 5.

As described above, the rotary sealing ring 72 is a metal molded product or a resin molded product, and it is preferable that at least the end face of the annular protrusion 75 inside the machine is made of a material having excellent slidability. In addition, the end face may be coated with SiC or the like.

The bellows portion 73 of the bellows 7 is formed in a bellows shape and is configured to expand and contract in the axial direction, and is in a state of bulging toward the outer diameter side due to the pressure inside the machine.

The retainer 8 is provided with a shaft hole 80 through which the bellows 7 is inserted, and has an annular shape. Further, the retainer 8 has an annular protrusion 81 protruding from the outer diameter side of the inner end surface 8a of the main body 85 toward the inside of the machine, and an outer diameter side of the outer end surface 8b of the main body 85 of the main body 85. An annular protrusion 82 that protrudes toward the outside of the machine is formed.

Further, the retainer 8 is made of metal and is externally fitted to the rotary sealing ring 72 of the bellows 7. Specifically, the retainer 8 has a shaft hole 80 formed in the annular main body 85 so that the bellows portion 73 of the bellows 7 can be inserted from the outside of the machine, and the main body 85 has a shaft hole 80 formed from the outer diameter side of the end surface 8a inside the machine. An annular protrusion 81 projecting inward is fitted onto the rotary sealing ring 72 of the bellows 7. At this time, the annular protrusion 81 of the retainer 8 and the flange 74 of the rotary sealing ring 72 of the bellows 7 face each other, and the end surface 8a on the inside of the retainer 8 and the end surface 72b on the outside of the rotary sealing ring 72 of the bellows 7 Is in contact with each other. According to this, the accuracy of assembling the retainer 8 to the rotary sealing ring 72 of the bellows 7 can be improved. The inner circumference of the shaft hole 80 of the retainer 8 is substantially in contact with the outer circumference of the bellows portion 73 of the bellows 7.

The annular protrusion 82 extending outward from the machine outside end surface 8b of the main body 85 of the retainer 8 is axially recessed at a position evenly distributed in the circumferential direction and is opened to the outside of the machine 83, 83, ..., 84. , 84, ... Are formed. Further, the inner peripheral surface 82a of the annular projecting portion 82 is radially separated from the outer periphery of the bellows portion 73 of the bellows 7 to form an annular space X. The space X is defined from the outer peripheral end surface 8b of the retainer 8, the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8, and the outer peripheral surface of the bellows portion 73 of the bellows 7, and is outside the machine on the inner diameter side of the retainer 8. It is open to the public.

The fixing / damping member 9 is mainly composed of an annular vibration damping member 91 and split clamps 92 and 92 (fixing members) divided into two in the circumferential direction, and the base end portion 71 of the bellows 7 is sleeve 6 It is fixed so as not to rotate in the circumferential direction with respect to the first outer peripheral surface 61 of the above. Since the split clamps 92 and 92 have substantially the same configuration, the structure of one split clamp 92 will be described, and the description of the other split clamp 92 will be omitted.

The vibration damping member 91 is provided with a shaft hole 90 through which the bellows 7 is inserted, and has an annular shape. Further, the vibration damping member 91 includes a main body portion 91d (protruding portion) forming a flange shape on the outer side of the machine and an annular protruding portion 91c protruding from the inner diameter side of the end surface 91a on the inner side of the machine to the inner side of the machine. Is formed. The outer diameter of the main body 91d of the vibration damping member 91 is substantially the same as the outer diameter of the annular protrusion 82 of the retainer 8.

Further, a plurality of notches 91f, 91f, ... Notched to the outer periphery of the vibration damping member 91 are formed at positions evenly distributed in the circumferential direction on the end surface 91b on the outer side of the vibration damping member 91. The inner diameter of the shaft hole 80 of the retainer 8 and the inner diameter of the shaft hole 90 of the vibration damping member 91 are substantially the same, and are in a state of being close to the outer circumference of the bellows portion 73 of the bellows 7.

The annular protrusion 91c of the vibration damping member 91 is formed with an annular recess 91e that is recessed on the inner diameter side on the outer circumference inside the machine, and an O-ring 103 (elastic member) is mounted on the annular recess 91e.

Further, the vibration damping member 91 is made of metal and is assembled in a state where the annular protrusion 91c is loosely fitted in the space X formed on the inner diameter side of the retainer 8. Specifically, the vibration damping member 91 is inserted into the bellows portion 73 of the bellows 7 from the outside of the machine with the retainer 8 fitted to the rotary sealing ring 72 of the bellows 7, and the end face inside the machine of the main body 91d. An annular protrusion 91c protruding from the 91a toward the inside of the machine is loosely fitted in the radial direction with respect to the space X formed on the inner diameter side of the annular protrusion 82 of the retainer 8. At this time, the O-ring 103 mounted on the annular recess 91e formed on the inner diameter side of the annular protrusion 91c of the vibration damping member 91 is in a state of being in pressure contact with the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8. It has become.

Further, a plurality of drive pins 93, 93, ... (Anti-rotation member) extending in the axial direction are provided on the end surface 91a inside the machine of the vibration damping member 91, and the tip portion inside the machine is an annular protrusion of the retainer 8 described above. It is inserted into the recesses 83, 83, ... Formed in the portion 82. According to this, the drive pins 93, 93, ... Are inserted into the recesses 83, 83, ... To move the rotary sealing ring 72 of the retainer 8 and the bellows 7 in the axial direction relative to the sleeve 6. , The rotary sealing ring 72 of the retainer 8 and the bellows 7 can be locked so as not to move relative to the sleeve 6 in the circumferential direction. Therefore, the rotational force of the sleeve 6 is transmitted to the rotary sealing ring 72 of the retainer 8 and the bellows 7 by the drive pins 93, 93, ..., And rotates together with the sleeve 6. The outer diameter of the drive pin 93 is slightly smaller than the inner diameter of the recess 83, and the dimensional difference between the two diameters is preferably controlled by the crushing allowance of the O-ring 103, that is, the inner diameter of the annular protrusion 82 of the retainer 8. The difference in outer diameter of the annular protrusion 91c of the vibration member 91 is substantially the same as or greater than that of the outer diameter, and the drive pin 93 can be slightly moved in the radial direction while being inserted into the recess 83.

Further, springs 94, 94, ... Are compressionally arranged between the end surface 91a inside the machine of the vibration damping member 91 and the recesses 84, 84, ... Formed in the annular protrusion 82 of the retainer 8. According to this, the rotary sealing ring 72 of the bellows 7 held by the retainer 8 is attached to the static sealing ring 5 side by applying the urging force in the axial direction from the springs 94, 94, ... To the retainer 8. It is pushed so that the end face inside the machine of the annular protrusion 75 of the rotary sealing ring 72 and the end face 5a outside the machine of the static sealing ring 5 are in close contact with each other. According to this, the sealing property on the sliding surface S of the mechanical seal 1 can be improved. Further, the sealing surface pressure of the sliding surface S can be secured even when the inside of the machine is at low pressure.

The split clamp 92 has an annular recess 92c that is recessed toward the outer diameter side on the inner circumference of the outer side of the machine of the main body portion 92e having a substantially arc shape, and protrudes from the outer diameter side of the end surface 92a inside the machine of the main body part 92e toward the outside of the machine. An annular protrusion 92d is formed.

Further, the split clamps 92 and 92 are made of metal, and are externally fitted with the annular recesses 92c and 92c fitted to the flange 71a formed on the base end portion 71 of the bellows 7, respectively, and the main body portion 92e. , 92e are tightened with the tightening bolt 95 and fixed integrally. According to this, since the annular recesses 92c and 92c of the split clamps 92 and 92 and the flange 71a formed at the base end portion 71 of the bellows 7 are fitted, they do not move relative to each other in the axial direction.

Further, the annular protrusions 92d and 92d of the split clamps 92 and 92 are fitted onto the outer periphery of the outside of the machine of the vibration damping member 91, so that the vibration damping member 91 and the split clamps 92 and 92 are integrally assembled. It is in a state of being At this time, since the split clamps 92 and 92 can be assembled in a state where the inner end faces 92a and 92a of the machine and the outer end faces 91b of the vibration damping member 91 are in contact with each other, the split clamp 92 with respect to the vibration damping member 91 can be assembled. , 92 can be assembled more accurately.

Further, the inner end faces 92a of the split clamps 92, 92 are provided with pins 96, 96, ... Extending in the axial direction, and a plurality of notches 91f, which are formed on the outer end faces 92b of the vibration damping member 91, It is inserted in 91f, ... According to this, the pins 96, 96 are inserted into the notches 91f, 91f, ... To prevent the vibration damping member 91 from moving relative to the sleeve 6 and the split clamps 92, 92 in the circumferential direction. Can be stopped. Therefore, the rotational force of the sleeve 6 and the split clamps 92, 92 is transmitted to the vibration damping member 91 by the pins 96, 96, ..., And rotates together with the sleeve 6 and the split clamps 92, 92.

The set ring 10 is made of metal and has an annular shape, is inserted through the first outer peripheral surface 61 of the sleeve 6, and is fixed to the sleeve 6 by the bolt 11 in a state of being in contact with the end surface 92b on the outer side of the machine of the split clamps 92 and 92. Has been done. According to this, each member inserted and assembled through the sleeve 6 is integrally held between the static sealing ring 5 inside the machine and the set ring 10 outside the machine by using the urging force of the springs 94, 94, ... can do. It is assumed that the set ring 10 is fixed at a position where the springs 94, 94, ... Apply a predetermined urging force to the retainer 8 in the axial direction.

The materials of the O-rings 101, 102, and 103 in the above embodiment are fluororubber, nitrile rubber, H-NBR, EPDM, perfluoroelastomer, and the like.

As described above, the mechanical seal 1 of the present embodiment is fixed to the space X formed between the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 and the outer periphery of the bellows portion 73 of the bellows 7. The annular protrusion 91c of the vibration damping member 91 constituting the vibration damping member 9 is loosely fitted in the radial direction, that is, the retainer 8 and the vibration damping member 91 are so-called spigot joints and are damped. The O-ring 103 provided in the annular recess 91e formed on the inner periphery of the annular protrusion 91c of the vibration member 91 is elastically deformed in the space X, so that the retainer for the fixing / vibration damping member 9 (vibration damping member 91) The relative movement of the retainer 8 in the radial direction is suppressed, and the shaft core of the retainer 8 is easily held in a state of being aligned with the shaft core of the fixing / damping member 9, so that the assembly accuracy of the retainer 8 can be improved. ..

Further, the vibration damping member 91 is integrally assembled with the split clamps 92 and 92 that constrain the base end portion 71 of the bellows 7 in the radial direction, and the vibration damping member 91 is further inside the machine (retainer) of the split clamps 92 and 92. Since it is arranged on the 8 side), the length of the vibration damping member 91 extending in the axial direction can be shortened. According to this, the accuracy of assembling the retainer 8 and the vibration damping member 91 can be improved.

Further, as shown in FIG. 2, the rotary sealing ring 72 of the bellows 7 is changed to the static sealing ring 5 by slightly deforming the bellows portion 73 of the bellows 7 due to centrifugal force due to the rotation of the rotating shaft 3, self-excited vibration, or the like. When a stress such as an inclination is applied to the bellows 7, the rotary sealing ring 72 and the retainer 8 of the bellows 7 are annularly projected from the outer end surface 5a of the static sealing ring 5 and the rotary sealing ring 72 due to the elastic deformation of the O ring 103. While maintaining the sliding surface S with the end surface inside the machine of the portion 75, the portion 75 moves in the radial direction (upper surface of FIG. 2) using the space X formed on the inner diameter side of the retainer 8.

The gap between the annular protrusion 91c in the state where the annular protrusion 91c of the vibration damping member 91 is loosely fitted with respect to the space X and the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 is the elasticity of the O-ring 103. It is larger than the crushing allowance due to deformation. According to this, when the O-ring 103 is elastically deformed, the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 is less likely to come into contact with the annular protrusion 91c of the vibration damping member 91. It is possible to prevent an excessive stress from acting between the protrusion 91c and the retainer 8.

Further, in the rotary sealing ring 72 and the retainer 8 of the bellows 7, the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 is restricted from moving in the radial direction due to the elastic deformation of the O-ring 103 (FIG. 2, below the paper surface). See side). Further, when a larger stress is applied, the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 substantially abuts on the annular protrusion 91c of the vibration damping member 91 that loosely fits into the space X, thereby increasing the radial direction. Relative movement is regulated (see the lower side of Fig. 2). At this time, since the O-ring 103 is in a state of being compressed between the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 and the annular protrusion 91c of the vibration damping member 91, the elastic force of the O-ring 103 As a result, the shaft core of the retainer 8 can be returned to the original position (the position where the rotating shaft 3 and the shaft core are shared). According to this, the vibration damping property of the retainer 8 can be enhanced.

Further, an O-ring 101 is arranged between the annular protrusion 42 of the case 4 and the annular protrusion 51 of the static sealing ring 5. According to this, when a large axial stress acts on the sliding surface S, the O-ring 101 is compressed, so that the axial stress acting on the sliding surface S can be released.

In this way, the mechanical seal 1 is inclined with respect to the sleeve 6, the fixing / damping member 9, and the base end portion 71 of the bellows 7, in which the rotary sealing ring 72 of the bellows 7 and the retainer 8 are fixed to the rotary shaft 3. Even when a large amount of stress is applied, it is possible to move in the radial direction and the axial direction while maintaining the sliding surface S. That is, in the mechanical seal 1, since the tilt of the rotary sealing ring 72 of the bellows 7 can be allowed while the sliding surface S is maintained, an excessive stress acts particularly between the retainer 8 and the vibration damping member 91. It's getting harder to do. Further, while maintaining the sliding surface S, the axial runout of the rotating shaft 3 (sleeve 6, fixing / damping member 9 and base end portion 71 of the bellows 7 which are fixed to the rotating shaft 3 and share the shaft core) And vibration can be tolerated, so that the vibration damping property of the entire mechanical seal 1 can be improved.

Further, as shown in FIG. 1, since the annular protrusion 91c of the vibration damping member 91 is loosely fitted in the space X formed on the inner diameter side of the retainer 8, a vibration damping mechanism is provided on the outer diameter side of the retainer 8. The mechanical seal 1 having high vibration damping property can be configured to be smaller than that of the above. Further, the diameter of the retainer 8 can be adjusted as appropriate.

Further, since the annular protrusion 91c of the vibration damping member 91 is loosely fitted in the space X formed on the inner diameter side of the retainer 8, it is fixed on the outer diameter side of the retainer 8 and between the vibration damping member 9 in detail. Is formed with an annular gap C between the annular protrusion 82 of the retainer 8 and the end surface 91a inside the machine of the vibration damping member 91, and confirms the assembled state of the retainer 8 with respect to the fixing / damping member 9 from the outer diameter side. can do.

Specifically, for example, when a damping body that extends from the fixing / damping member 9 side and abuts from the outer diameter side of the retainer 8 in the circumferential direction is provided, the fixing / damping member is fixed / damping. Since a part of the member 9 and the retainer 8 (fixed / damping member 9 side) is covered from the outer diameter side by the damping body, check the assembled state of the retainer 8 with respect to the fixed / damping member 9 from the outer diameter side. I can't. In this case, when the vibration damping body is brought into contact with the retainer 8 from the outer diameter side, the shaft core of the retainer 8 may be displaced from the fixing / vibration damping member 9, and the assembly accuracy may be lowered.

However, in the mechanical seal 1 of the present embodiment, since the annular protrusion 91c of the vibration damping member 91 that suppresses the retainer 8 is loosely fitted on the inner diameter side of the retainer 8, the fixing / vibration damping member 9 and the retainer 8 An annular gap C is formed between the two. According to this, the distance C between the fixing / damping member 9 fixed to the rotating shaft 3 and sharing the shaft core and the retainer 8 is assembled substantially uniformly in the circumferential direction, in other words, fixed. -Since it can be confirmed from the outer diameter side that the shaft cores of the retainer 8 are aligned with the vibration damping member 9, the assembly accuracy of the retainer 8 can be improved.

Further, a flange-shaped main body portion 91d is formed inside the machine of the vibration damping member 91 constituting the fixing / vibration damping member 9, and the outer peripheral surface of the annular protrusion 82 of the retainer 8 and the main body portion of the vibration damping member 91 are formed. An annular gap C is formed between the 91d and the outer peripheral surface. According to this, since the annular gap C is formed at the position on the outer diameter side, it becomes easier to check the assembling state of the retainer 8 with respect to the fixing / damping member 9 from the outer diameter side, and the assembling accuracy of the retainer 8 can be improved. It can be further enhanced. Since the main body portion 91d of the vibration damping member 91 is formed on the base end portion 71 side of the bellows 7, is externally fitted by the split clamps 92 and 92, and is fixed to the sleeve 6 together with the base end portion 71 of the bellows 7. The rotation shaft 3 and the shaft core are easily aligned with each other, and the accuracy of confirming the assembled state of the retainer 8 with respect to the fixing / damping member 9 based on the above-mentioned annular gap C is improved.

Further, the annular protrusion 91c of the vibration damping member 91 is loosely fitted to the retainer 8 on the inner diameter side of the drive pins 93, 93, .... According to this, the positions of the drive pins 93, 93, ... Are confirmed from the annular gap C formed between the outer peripheral surface of the annular protrusion 82 of the retainer 8 and the outer peripheral surface of the main body 91d of the vibration damping member 91. At the same time, since it can be inserted into the recesses 83, 83, ... Formed in the annular protrusion 82 of the retainer 8, the fixing / vibration damping member 9 (vibration damping member 91) and the retainer 8 can be easily assembled. be able to.

Further, since the annular protrusion 91c of the vibration damping member 91 and the drive pins 93, 93, ... Are provided so as to be parallel to the end surface 91a inside the machine of the vibration damping member 91 in the axial direction, the retainer 8 is annular. The accuracy of the insertion position of the drive pins 93, 93, ... With respect to the recesses 83, 83, ... Formed in the protrusion 82 is high.

Further, since the vibration damping member 91 has an annular structure and the annular protrusion 91c that controls vibration by being loosely fitted on the inner diameter side of the retainer 8 has an integral structure, the annular protrusion 91c is divided in the circumferential direction. It is possible to eliminate the radial deviation and the axial deviation of the annular protrusion 91c, and to improve the vibration damping property.

Further, the fixing / vibration damping member 9 is provided with an annular vibration damping member 91 and split clamps 92 and 92 separately, and the annular vibration damping member 91 is attached to the bellows portion 73 of the sleeve 6 and the bellows 7. After inserting from the outside, the annular protrusion 91c of the vibration damping member 91 is loosely fitted on the inner diameter side of the retainer 8, and the split clamps 92 and 92 are externally fitted to the vibration damping member 91 and assembled integrally, and at the same time, the base of the bellows 7. Since the end portion 71 can be fixed to the sleeve 6, the assembleability of the mechanical seal 1 can be improved.

In the mechanical seal 1 of this embodiment, the split clamps 92 and 92 are integrally assembled by being fitted to the vibration damping member 91, and the vibration damping member 91 is attached to the split clamps 92 and 92. There is no deformation of the vibration damping member 91 that occurs when the damping member 91 is integrally fixed by tightening with a bolt or the like in the circumferential direction. Therefore, it does not affect the vibration damping property and the assembly accuracy of the retainer 8.

The inner diameter of the retainer 8 and the inner diameter of the vibration damping member 91 (the diameters of the shaft hole 80 of the retainer 8 and the shaft hole 90 of the vibration damping member 91) are substantially the same, and the bellows portion 73 of the bellows 7 is omitted in the axial direction. It covers. According to this, it is possible to suppress the radial deformation of the bellows portion 73 due to centrifugal force, pressure and the like.

The material of the stationary sealing ring 5 and the rotary sealing ring 72 of the bellows 7 may be an ultra-hard material such as silicon carbide, tungsten carbide, carbon, or other ceramics.

Further, as the spring 94, a wave coil spring or the like may be used in addition to the coil spring.

Although examples of the present invention have been described above with reference to the drawings, the specific configuration is not limited to these examples, and any changes or additions within the scope of the gist of the present invention are included in the present invention. Is done.

For example, in the above embodiment, the fixing / vibration damping member 9 has been described as having the annular vibration damping member 91 and the split clamps 92 and 92 as separate bodies, but the present invention is not limited to this, and for example, the fixing / vibration damping member 9 is fixed. The vibration damping member constituting the vibration damping member and one of the split clamps may be integrally molded, and the other split clamp may be assembled.

Further, in the above embodiment, the mechanical seal 1 has been described as a rotary mechanical seal in which the springs 94, 94, ... Are rotated together with the rotating shaft 3, but the mechanical seal 1 may be a fixed mechanical seal.

Further, in the above embodiment, the mode in which the bellows 7 is fixed to the sleeve 6 which is the member on the rotating shaft side has been described, but the present invention is not limited to this, and the bellows is directly fixed to the rotating shaft without using the sleeve. You may.

Further, in the above embodiment, the structure in which the springs 94 and 94 urge the rotary sealing ring 72 of the bellows 7 via the retainer 8 has been described, but the present invention is not limited to this, and the spring directly contacts the rotary sealing ring of the bellows. The structure may be urged.

Further, in the above embodiment, the example in which the O-ring 103 is pressed against the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8 has been described, but the present invention is not limited to this, and the O-ring is the annular protrusion of the retainer. It may be slightly in contact with the inner peripheral surface and not compressed, or may be in a non-contact state with the inner peripheral surface of the annular protrusion of the retainer.

Further, the O-ring 103 may be provided on the inner peripheral surface 82a of the annular protrusion 82 of the retainer 8.

Further, in the above embodiment, the example in which the recess 83 is provided in the retainer 8 and the drive pin 93 is provided in the vibration damping member 91 has been described, but the present invention is not limited to this, and the recess 83 is provided in the vibration damping member 91 and the drive is provided. The pin 93 may be provided on the retainer 8. Similarly, the notch 91f may be provided in the split clamp 92 and the pin 96 may be provided in the damping member 91. Further, the recess 84 may be provided in the vibration damping member 91.

1 Mechanical seal 2 Housing 3 Rotating shaft 4 Case 5 Rest-sealing ring 6 Sleeve (Rotating shaft side member)
7 Bellows 8 Retainer 9 Fixing / damping member 10 Set ring 72 Rotating sealing ring (rotating sealing part)
91 Vibration damping member 91c Circular protrusion 91d Main body (protrusion)
92 Split clamp (fixing member)
93 Drive pin (anti-rotation member)
94 Spring 96 Pin 101-103 O-ring S Sliding surface X Space C Gap

Claims (5)

With a static sealing ring,
A bellows having a rotary sealing portion that slides relative to the static sealing ring in response to the rotation of the rotating shaft and a base end portion provided on the side opposite to the rotary sealing portion in the axial direction.
A retainer that holds the rotary seal portion from the radial direction,
A fixing / vibration damping member that fixes the base end portion to the rotating shaft side member and is loosely fitted to the retainer in the radial direction.
A spring that urges the static sealing ring and the rotary sealing portion in the axial direction so as to bring them close to each other.
At the site where the retainer and the fixing / damping member are loosely fitted, the retainer and the fixing / damping member
It is equipped with an elastic member provided between the damping members .
The fixing and damping members, mechanical seals, characterized in Rukoto is loosely fitted on the inner diameter side of the retainer. The mechanical seal according to claim 1 , wherein the fixing / vibration damping member is provided with a protruding portion protruding toward the outer diameter side. A detent member for detenting the fixing / damping member and the retainer so that they do not rotate relative to each other is provided.
The mechanical seal according to claim 1 or 2 , wherein the fixing / damping member is loosely fitted with the retainer on the inner diameter side of the detent member. The fixing / vibration damping member includes a fixing member that fixes the base end portion to the rotating shaft and a vibration damping member that is loosely fitted with the retainer.
The mechanical seal according to any one of claims 1 to 3 , wherein the fixing member and the vibration damping member are provided separately. The fixing member is a split clamp.
The mechanical seal according to claim 4 , wherein the vibration damping member is an annular body.

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