The present invention relates to a split type mechanical seal device adapted such that two portions into which a seal ring is split parallel to a shaft direction are assembled from both sides around an outer circumferential surface of a rotary shaft fitting in a machine so as to join split surfaces of the two portions to each other. More particularly, the present invention relates to a mechanical seal device in which sealing capability of the split type seal ring is improved.
Related technologies of the present invention include a mechanical seal device 100 illustrated in
Inside an inner circumferential surface 141 of the gland assembly 140, a mechanical seal is arranged. The mechanical seal is provided with a holder assembly 102, which is fitted into the rotary shaft 148 to rotationally move together, and split into two portions parallel to the shaft direction. Split surfaces of the two portions of the holder assembly 102 are also joined to each other, and integrally tighten with a plurality of unshown bolts. Also, between an outer circumferential surface of the holder assembly 102 and the inner circumferential surface 141 of the gland assembly 140, a fluid passage 142 through which a sealing target fluid circulates is formed. Further, an annular groove 105 provided on the housing side of an inner circumferential surface of the holder assembly 102 is fitted therein with a first O-ring 131 to seal the fitting portion between the rotary shaft 148 and the holder assembly 102. Also, a concave portion 146 is provided inside one end of the holder assembly 102, and a drive pin 135 is implanted into and bonded to the innermost part of an inner circumferential surface of the concave portion 146. In addition, around an outer part of the inner circumferential surface of the concave portion 146, a first step portion 145 for an O-ring formed to have a larger diameter is further provided.
In the concave portion 146 of the holder assembly 102, a rotary seal ring 101, which is split into two portions parallel to the shaft direction, is fitted. The rotary seal ring 101 is provided at one end thereof with a sealing surface for rotation 106. Also, the rotary seal ring 101 is provided at the other end with a locking hole 103, which engages with the drive pin 135, and the rotary seal ring 101 is locked by the drive pin 135 upon rotation. Further, between the first step portion 145 of the holder assembly 102 and an outer circumferential surface of the rotary seal ring 101, a space portion 133 for an O-ring is formed, and in the space portion 133, a second O-ring 132 is provided. The second O-ring 132 tightens the two portions of the 2-split type rotary seal ring 101 so as to bring split surfaces of the two portions into close contact with each other, and blocks the space portion 133. Also, the space portion 133 is formed with a flow-in port 144 through which the sealing target fluid flows in.
A fixed seal ring 110, which is provided at an end surface thereof with a sealing surface for fixing 111 coming into close contact with the sealing surface for rotation 106 and split into two portions parallel to the shaft direction, is fitted at an inner circumferential surface 112 thereof into the rotary shaft 148 at an interval. An outer circumferential fitting surface S of the fixed seal ring 110 is movably fitted into a stepped inner circumferential surface having a small diameter, which is arranged inside a space forming surface 143 of the gland assembly 140 and around an outer part of the space forming surface 143. Also, the fixed seal ring 110 is pressed toward the rotary seal ring 101 by a plurality of plate springs 130 that are provided on an end surface of the gland assembly 140 at equal intervals in a circumferential direction. Further, between the fitting surface S of the fixed seal ring 110 and the space forming surface 143, a space 114 for an O-ring is formed. In the space 114, a third O-ring 137 is fitted. The third O-ring 137 tightens the fitting surface S so as to bring split surfaces of the two portions, into which the fixed seal ring 110 is split, into close contact with each other, and blocks the space 114 from the outside.
In the mechanical seal device 100 configured as above, the mechanical seal should be formed inside the split type gland assembly 140 provided in the mechanical seal device 100, so that a combination of the gland assembly 140, holder assembly 102, and mechanical seal becomes complicated in structure and large. Also, the mechanical seal device 100 is configured such that the fluid passage 142 through which the sealing target fluid circulates is provided between the gland assembly 140 and the holder assembly 102, so that it is of the so-called inside seal type, and therefore becomes larger in structure.
Further, each of the sealing surface for rotation 106 of the rotary seal ring 101 and that for fixing 111 of the fixed seal ring 110 is split into two portions, so that split surfaces of the two portions of each of the sealing surface for rotation 106 and that for fixing 111 may have a microscopic step therebetween upon rotation. Even if the step is microscopic, it causes both of the sealing surfaces 106 and 111 to wear upon rotation to thereby reduce sealing capability. In particular, if the sealing target fluid is gas, lubricating action due to liquid does not arise between the sealing surface for rotation 106 of the rotary seal ring 101 and that for fixing 111 of the fixed seal ring 100, so that fluctuations of the split surfaces facilitate the wearing of the both sealing surfaces 106 and 111 upon rotation. Also, both of the sealing surfaces 106 and 111 may cause a squeal phenomenon of generating noise due to dry friction upon sliding, so that the respective joining split surfaces induce repetitive and fine movements, resulting in rapid wearing of the both sealing surfaces 106 and 111. Further, if both of the seal rings 101 and 111 are made of a hard material such as silicon carbide in order to improve wear resistance, sliding heat generation may rapidly occur. Accordingly, because the sliding heat generation occurs in the both sealing surfaces 106 and 111 in addition to the squeal phenomenon, the second and third O-rings 132 and 137 are heated due to the sliding heat generation to loose elasticity, resulting in a reduction of the sealing capability.
The present invention is made in consideration of the problems as described above, and an object thereof for solving such technical problems is to reduce the friction of the sealing surfaces of the mechanical seal device upon sliding and also to prevent the sealing surfaces from wearing. Another object of the present invention is to prevent the sealing surfaces and joining split surfaces of the seal rings from abnormally wearing. Still another object of the present invention is to prevent seizure of the sealing surfaces and the squeal phenomenon in the dry friction condition of the sealing surfaces upon rotation. Yet another object of the present invention is to simplify a structure of the mechanical seal device and facilitate assembly and decomposition of it to thereby reduce assembly and decomposition cost.
The present invention is made in order to solve the technical problems as described above, and technical means for solving them is configured as follows.
A mechanical seal device according to the present invention is intended for sealing a sealing target fluid between a hole of a housing and a rotary shaft inserted into said hole inside a machine, the mechanical seal device being attached to an outer side of the machine, and comprises: a split stationary seal ring to be fixed having: a fitting surface on an outer circumference, the fitting surface being hermetically fitted into a circumferential surface of the hole of said housing and held movably in a shaft direction; a first outer circumferential surface formed on said outer circumference; a sealing surface on an end surface in the shaft direction; and a plurality of first split contact surfaces capable of being closely joined to one another, the plurality of first split contact surfaces being exposed by splitting the split stationary seal ring parallel to the shaft direction;
The mechanical seal device according to the present invention is simplified in structure, and in order to facilitate assembly thereof, configured to be of an outside seal type that seals the sealing target fluid on the inner circumferential side of the sealing surface of the split stationary seal ring. For this reason, if the high-pressure sealing target fluid acts, it is likely to leak from between both of the sealing surfaces, as compared with an unsplit seal ring. However, because the sealing layer made of resin or rubber is coated on at least one of the sealing surfaces of the both seal rings, the sealing target fluid can be effectively prevented from leaking even if the high pressure acts on the sealing surface of the split type seal ring. Consequently, even such split type seal ring can reliably seal the sealing target fluid having pressure ranging from low to high.
In the split type seal ring, the sealing surfaces are split, so that minute steps may arise on both of the sealing surfaces during rotation. Even if the steps on the sealing surfaces are minute, they wear the sealing surfaces during rotation, and therefore reduce their sealing capability. However, providing the sealing layer made of resin or rubber on the sealing surface enables the sealing surface to be effectively prevented from wearing. Also, even if the sealing target fluid is gas, the sealing layer can prevent the squeal phenomenon upon sliding, and friction and wearing even in the dry friction condition. Further, the sealing layer does not require an expensive material for the split type seal ring, so that an inexpensive material can be used for production, and therefore cost can be significantly reduced.
A mechanical seal device according to a preferred embodiment of the present invention will hereinafter be described in detail on the basis of the drawings. Note that each of the drawings to be illustrated below is an accurate one based on a design.
A fitting surface 2D1 of the split stationary seal ring 2, which is split into two portions parallel to the shaft direction, is movably fitted into the hole circumferential surface 60A of the housing 60. The split stationary seal ring 2 is made of silicon carbide, and formed in an annular seal ring shape by joining a first split contact surface 2J of the one portion of the split stationary seal ring (2X) and that of the other portion of the split stationary seal ring (2Y) to each other (see
A gap between the inner circumferential surface 2C and the rotary shaft 50 is communicatively connected to the circulating path A1. Also, an end surface of the split stationary seal ring 2 is provided with a sealing surface 2A. Further, a first outer circumferential surface 2D having a diameter larger than that of the fitting surface 2D1 is formed on an outer circumferential side of the split stationary seal ring 2. A boundary part between the fitting surface 2D1 and the first outer circumferential surface 2D forms into a first step surface 2B. The first step surface 2B and the sealing surface 2A are preferably formed to be parallel to each other with high accuracy (for more detail, see the enlarged diagram,
Also, onto the sealing surface 2A of the split stationary seal ring 2, a first sealing layer 10A made of a resin material is joined with an adhesive. The first sealing layer 10A may be made of a rubber material depending on a type of the sealing target fluid. As a material for the first sealing layer 10A, a material such as polyamide, polytetrafluoroethylene (PTFE), fluororesin, perfluoroelastomer, or fluororubber is used depending on an operating temperature or wear resistance. Also, the first sealing layer 10A is provided with a cut surface for insertion (not shown) formed by radially or obliquely cutting a part of the first sealing layer 10A. If the first sealing layer 10A is thick, the cut surface may be formed to be slanted in the thickness direction. The first sealing layer 10A is expanded from the cut surface for insertion, and then laterally inserted and fitted in a radial direction of the rotary shaft 50. Subsequently, the first sealing layer 10A is joined to the sealing surface 2A with the adhesive.
Alternatively, the first sealing layer 10A may be formed by being preliminarily coated on the sealing surfaces 2A and 2A of the both portions 2X and 2Y of the halved split stationary seal ring 2. Still alternatively, the first sealing layer 10A may be coated on the sealing face 2A after the split stationary seal ring 2 has been fitted around the rotary shaft 50. The first sealing layer 10A is formed to have a thickness range of 0.01 mm to 2 mm; however, there is an example where the thickness is designed in the range of 0.005 mm to 3.2 mm in consideration of a lifetime due to wearing, or the like. Also, the stationary seal ring 2 may be formed such that a back surface thereof on the sealing target fluid side has an area larger than that of the sealing surface 2A to make pressure of the sealing target fluid act on the back surface, and thereby surface pressure on the sealing surface 2A may be increased. As described, even if the pressure of the sealing target fluid acts on the split stationary seal ring 2, the wear resistance and sealing capability of the split stationary seal ring 2 can be maintained high due to the elasticity of the first sealing layer 10 provided on the sealing surface 2A. Note that in
Also, on the front surface of the first tightening ring 7 illustrated in
Also, first split elastic rings 9A and 9A into which a cylindrical body is split are provided so as to face to each other between the first outer circumferential surface 2D of the split stationary seal ring 2 and the first tightening surface 7C of the first tightening ring 7. The joined first split elastic rings 9A prevent deformation of the sealing surface 2A, which is due to elastic deformation of the split stationary seal ring 2 occurring when the split stationary seal ring 2 is tightened by the first tightening ring 7. As a result, the sealing surface 2A can exercise its sealing capability. Also, a material for the first split elastic ring 9A is a rubber or resin material. Further, the first split elastic ring 9A is adapted to have a thickness ranging from 0.05 mm to 3 mm. Preferably, the thickness is in the range of 0.08 mm to 2 mm. If the thickness of the first split elastic ring 9A is too large, tightening becomes insufficient. On the other hand, if it is too small, the deformation of the first stationary seal ring 2 is induced. Note that the thickness of the first split elastic ring 9A is not limited to the above dimension range, but may be designed depending on a dimension of a diameter of the split stationary seal ring 2.
The fitting holes 7H provided on the first tightening ring 7 are used for spring seats. One ends of the coil springs 11 are inserted into the fitting holes 7H, and placed on the spring seats in the fitting holes 7H, respectively. Also, the other ends of the coil springs 11 are connected to the side of the housing 60 on the outside B of the machine. In addition, between the side on the outside B of the machine and an end surface of the first tightening ring 7, two semicircular spacers 5 into which a cylindrical body is split are annularly fitted. The spacers 5 also enable the first tightening ring 7 to be stably fitted even if the side on the outside B of the machine is roughly finished.
An end surface of the split rotary seal ring 12 is formed as an opposed sealing surface 12A. The opposed sealing surface 12A is formed so as to come into contact with the sealing surface 2A of the split stationary seal ring 2 to seal the sealing target fluid. Also, an outer circumference of the split rotary seal ring 12 forms into a second outer circumferential surface 12D and a third outer circumferential surface 12D1 having a diameter smaller than that of the second outer circumferential surface 12D on the outside B of the machine. Further, a boundary part between the second outer circumferential surface 12D and the third outer circumferential surface 12D1 forms into a second step surface 12B. The split rotary seal ring 12 is, similarly to the split stationary seal ring 2, made of a material such as silicon carbide, carbon, ceramic, or hard resin material. Also, the split rotary seal ring 12 is preferably made of a material that can be broken to form the second split contact surfaces 12J and 12J, as well.
Further, a second sealing layer 10B made of a resin material is joined to the opposed sealing surface 12A of the split rotary seal ring 12 with an adhesive, as well. The second sealing layer 10B may be made of a rubber material depending on a type of the sealing target fluid. As a material for the second sealing layer 10B, a material such as polyamide, polytetrafluoroethylene (PTFE), fluororesin, perfluoroelastomer, or fluororubber is used depending on an operating temperature or wear resistance. Also, the second sealing layer 10B is provided with a cut surface for insertion formed by cutting a part of the second sealing layer 10B radially or obliquely with respect to the radial direction.
The second sealing layer 10B is expanded from the cut surface for insertion, and then laterally inserted and fitted in a radial direction of the rotary shaft 50. Subsequently, the second sealing layer 10B is joined to the opposed sealing surface 12A with the adhesive. Alternatively, the second sealing layer 10B may be formed by being preliminarily coated on the opposed sealing surfaces 12A and 12A of the both portions 12X and 12Y of the halved split rotary seal ring 12. Still alternatively, the second sealing layer 10B may be formed by being coated on the opposed sealing surface 12A after the split rotary seal ring 12 has been fitted around the rotary shaft 50. The second sealing layer 10B is formed to have a thickness range of 0.01 mm to 2 mm; however, there is an example where the thickness is designed in the range of 0.005 mm to 3.2 mm in consideration of a lifetime due to wearing, or the like. Note that in
An illustration of a second tightening ring 17 fitted on the second outer circumferential 12D side of the split rotary seal ring 12 is omitted because the second tightening ring 17 can be illustrated as a diagram similar to the elevational view of the first tightening ring 7 as viewed from the opposed sealing surface 12A side. In addition, the second tightening ring 17 has a shape almost symmetrical to that of the first tightening ring 7. The second tightening ring 17 is split along its center line as viewed from its front surface, i.e., parallel to the shaft direction, to form into a third split tightening ring 17A on one side and a fourth split tightening ring 17B on the other side. Also, the second tightening ring 17 is halved along the center line, i.e., parallel to the shaft direction, to form two second split surfaces (for details on the shape, see the first tightening ring 7 in
As a result, the opposed sealing surface 12A can exercise its sealing capability. The second tightening surface 17C on an inner circumferential surface of the second tightening ring 17 is formed on an end side thereof with a second supporting surface 17C1 forming into a step surface. The second tightening surface 17C of the second tightening ring 17 is fitted into the second outer circumferential surface 12D of the split rotary seal ring 12, and the second supporting surface 17C1 is locked by the second step surface 12B. Also, two second locking grooves 3B for drive pins are formed at an equal distance (or symmetrically in position) on an outer circumferential surface of the second tightening ring 17.
On a side of the second tightening ring 17, a third tightening ring 40 is fitted around the rotary shaft 50. The third tightening ring 40 is equally split into two portions parallel to the shaft direction, and the two portions of the third tightening ring (40 and 40) are connected to each other by bringing split surfaces of the both portions into contact with each other with a plurality of bolts 39, and tightening an inner circumferential connecting surface 40C around the rotary shaft 50. On an inner circumferential side of a side of the third tightening ring 40, an annular convex portion 40D is formed, and the annular convex portion 40D presses the second O-ring 37. Also, the side of the third tightening ring 40 and that of the second tightening ring 17 may be connected to each other with unshown bolts to make a connection between the second tightening ring 17 and the split rotary seal ring 12. Further, a drive pin 43 B is screwed into and fixed to the side of the third tightening ring 40, and locked into the second locking hole 3B of the second tightening ring 17 to thereby rotationally move the second tightening ring 17 and the split rotary seal ring 12 along with the rotary shaft 50 (see also
In
Also, the second tightening ring 17 is provided with the second locking hole 3B. The drive pin 43B is screwed into and fixed to a side of the third tightening ring 40 at a position corresponding to that of the second locking hole 3B. Then, the drive pin 43B is engaged with the second locking hole 3B to configure the rotary shaft 50 to transmit torque to the second tightening ring 17. Such a configuration in which the first and second tightening rings 7 and 17 are respectively provided with the first locking hole (unshown) and the second locking hole 3B enables the first and second tightening rings 7 and 17 to be miniaturized. Also, the configuration enables the first and second tightening rings 7 and 17 to be easily produced. Further, the configuration can make unnecessary the first split elastic ring 9A provided between the first outer circumferential surface 2D of the split stationary seal ring 2 and the first tightening surface 7C of the first tightening ring 7. By configuring as above, the mechanical seal device becomes simple in structure and easy in assembly. The rest of the configuration in this embodiment is almost the same as that of the mechanical seal device 1 in
Also, the second split elastic ring 9B is provided between the second tightening surface 17C of the second tightening ring 17 and the second outer circumferential surface 12D of the split rotary seal ring 12, similarly to the case of the first tightening ring 7. The second split elastic ring 9B produces a working effect similar to that of the first split elastic ring 9A.
In the mechanical seal device 1 configured as above, the sealing target fluid circulating through the circulating path A1 flows inside the inner circumferential surface 2C of the split stationary seal ring 2. However, the sealing surface 2A of the split stationary seal ring 2 provided with the first sealing layer 10A and the opposed sealing surface 12A of the split rotary seal ring 12 provided with the second sealing layer 10B come into close contact with each other to seal the sealing target fluid. As a result, even if the split stationary seal ring 12 and split rotary seal ring 12 are split parallel to the shaft direction, both of the sealing surfaces 2A and 12A reduces a friction coefficient, as well as exercising their sealing capability.
Further, both of the sealing surfaces 2A and 12A are provided with the sealing layers 10A and 10B, respectively, so that even if the sealing target fluid is gas, and even in a dry friction condition, the respective sealing surfaces 2A and 12A are prevented from wearing while preventing the squeal phenomenon upon sliding. As a result, the respective sealing surfaces 2A and 12A can exercise their sealing capability. Also, a sealing structure of the mechanical seal device 1 can be simplified, and the high-pressure sealing target fluid can be sealed. Further, even if the sealing target fluid is a highly viscous and highly slurry chemical solution, the split stationary seal ring 2 can exercise the sealing capability without attachment of the sealing target fluid. In addition, the sliding may be performed with only the first sealing layer 10A being provided on the sealing surface 2A of the split stationary seal ring 2 but the second sealing layer 10B not being provided on the opposed sealing surface 12A. In such a case, it is necessary to slightly increase the thickness of the first sealing layer 10A.
Inventions according to the other embodiments related to the present invention are described below in terms of their configurations and working effects.
A mechanical seal device according to a first invention of the present invention has coating layers made of a rubber or resin material brought into close contact between the first split contact surfaces of the split stationary seal ring and between the second split contact surfaces of the split rotary seal ring.
According to the mechanical seal device of the first invention, the split contact surfaces can be effectively prevented from being damaged even if vibration occurs during operation, because the coating layer is present between split contact surfaces. Also, for easy adaptation, each of the contact surfaces is configured to be a fractured surface; however, providing the coating layer between the fractured split contact surfaces enables friction between the split contact surfaces to be prevented. Further, the coating layer can reliably seal the sealing target fluid from leaking from between the split contact surfaces. Still further, the outer circumferential surface of the seal ring is tightened by the split tightening ring; however, by providing the coating layer between the split contact surfaces, the split contact surfaces are not damaged even if the outer circumferential surface of the seal ring is tightened more than enough, and deformation of the sealing surface due to the tightening can be prevented. As a result, an effect of improving the sealing capability of the sealing surface of the seal ring can be expected.
In a mechanical seal device according to a second invention of the present invention, the split stationary seal ring has a first step surface between the first outer circumferential surface formed larger in diameter than the fitting surface and the fitting surface; the first tightening surface of the first tightening ring has the first supporting surface for locking the first step surface; the split rotary seal ring has the third outer circumferential surface smaller in diameter than the second outer circumferential surface at an end of the second circumferential surface, and the second step surface between the second outer circumferential surface and the third outer circumferential surface; the second tightening surface of the second tightening ring has the second supporting surface for locking the second step surface; and the first tightening ring and the second tightening ring are formed in shapes almost symmetrical to each other, the first supporting surface supports the first step surface, and the second supporting surface supports the second step surface.
According to the mechanical seal device of the second invention, the first tightening ring and the second tightening ring are formed in almost symmetrical shapes, i.e., formed in the almost same shape, so that both of the components can be made common, and therefore production cost can be reduced. Also, the sealing capability of the sealing surface can be exercised, and the sealing surface can also be prevented from seizing and wearing. Further, the first supporting surface and the second supporting surface are formed in symmetrical shapes, so that force acting from both sides presses on the rear surfaces of the both seal rings at symmetrical positions, and therefore equally acts on the sealing surfaces. As a result, the sealing surfaces can be expected to exercise their sealing capability. Still further, the first supporting surface and the second supporting surface are formed in symmetrical shapes, so that both of the components can be made common and miniaturized, and therefore component cost can be reduced. Also, assembly of the both split tightening rings is simplified.
In a mechanical seal device according to a third invention of the present invention, the outer circumference of the first tightening ring has the first locking groove in the shaft direction; the housing has the fixing pin fixed thereon in the shaft direction; and the fixing pin engages with the first locking groove in the shaft direction to fix the first tightening ring.
According to the mechanical seal device of the third invention related to the present invention, the fixing pin is configured to engage with the first locking groove in the shaft direction, and thereby fix the first tightening ring to prevent it from rotationally moving, so that the fitting surface of the split stationary seal ring can be inserted into the hole of the housing, and simultaneously the fixing pin can be inserted into the first locking groove of the first tightening ring. For this reason, it becomes extremely easy to attach the split stationary seal ring to the housing. Also, the split stationary seal ring becomes simple in structure, and therefore production cost can be reduced.
The mechanical seal device can be assembled without removing the rotary shaft of the machine from the machine, and is therefore useful. Also, even if the mechanical seal device is of a split type, it is useful because the respective sealing surfaces can be prevented from wearing and exercise their sealing capability. Further, the mechanical seal device is simple in structure and can be easily assembled, and is therefore useful because of its low assembly cost.
Number | Date | Country | Kind |
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2005-333318 | Nov 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2006/322983 | 11/17/2006 | WO | 00 | 5/16/2008 |