The present invention relates to a mechanical seal arrangement having an improved flow behaviour for a medium supplied to the slide rings of a mechanical seal, more particularly a cooling and/or sealing medium.
Mechanical seal arrangements are known from the prior art in different designs. Typically, mechanical seal arrangements are supplied with a cooling and/or sealing medium which is conveyed by means of internal conveying devices. An example of this is known from DE 10 2011 118 294.6, wherein a tesla pump is used therein as the internal conveying device. Other conveying devices include, for example, pump rings. A fluid path extends from the internal conveying device to the slide rings from where it is discharged via an exit bore in a housing. The exit bore is, in this case, provided radially with respect to the slide rings. However, the fluid supplied to the mechanical seal must undergo several changes in direction owing to the rotation of the rotating slide ring and the axial supply, whereby flow losses may occur in the fluid. However, a greater power must therefore be applied by the internal conveying device. In particular, the fluid is accelerated in the peripheral direction in the region of the mechanical seal owing to the rotating slide ring, but must then be radially discharged.
It is thus the object of the present invention to provide a mechanical seal arrangement which allows internal losses in a fluid supplied to the slide rings to be reduced whilst having a simple design and being simple and cost-effective to produce.
This object is achieved by a mechanical seal arrangement having the features of claim 1. Preferred developments of the invention are described in the dependent claims.
The mechanical seal arrangement in accordance with the invention having the features of claim 1 is advantageous in that flow losses of a fluid supplied to the slide rings of a mechanical seal, such as, for example, a sealing medium or a cooling medium, are significantly reduced. A low-loss flow is achieved in this case within the mechanical seal arrangement, whereby in particular a mass flow of the supplied fluid can be increased with a conveying device having the same drive power. As a result, for example, an improved cooling effect can be achieved on the slide rings without as a result dimensions having to be increased for an outflow bore in a housing or the power of an internal conveying device having to be increased. In accordance with the invention, the mechanical seal arrangement comprises, in addition to the mechanical seal having a rotating slide ring and a stationary slide ring, a housing component having an inner, cylindrical peripheral region. The housing component comprises an outlet opening for discharging the fluid supplied to the slide ring and an inflow region. The inflow region allows, in accordance with the invention, flow losses to be reduced in the region of the entrance of the outlet opening. The inflow region includes at least one transition channel which extends in the circumferential direction and becomes continually deeper towards the outlet opening. This transition channel is formed in the housing component on the inner, cylindrical peripheral region and opens into the outlet opening.
In a particularly preferred manner, the outlet opening is arranged in the radial direction outside of the slide rings. In a particularly preferred manner, the outlet opening lies in the radial direction completely over the rotating slide ring or over the sealing gap. The fluid accelerated in the circumferential direction by the rotating slide ring is hereby supplied into the transition channel and then into the outlet opening with reduced flow losses.
The mechanical seal arrangement preferably further includes an internal conveying device. In a particularly preferred manner, the internal conveying device is a pump ring or a tesla pump. In a particularly preferred manner, the transition channel(s) of the outlet opening lie(s) in the radial direction over the internal conveying device. This ensures that the fluid conveyed by the internal conveying device can flow directly into the transition channels and thus the outlet opening. Preferably, the outlet opening is arranged radially outside and over the internal conveying device. In a further preferred manner, it is possible for two internal conveying devices to also be provided, said conveying devices being connected one behind the other, e.g. a pump ring and a tesla pump.
It is further preferred for the outlet opening to be oriented at an angle to the radial direction of the slide rings and for the transition channel to open into the outlet opening thus inclined with respect to the radial direction. In a particularly preferred manner, the outlet opening includes an intake region inclined with respect to the radial direction of the slide rings and a main region extending in the radial direction, wherein preferably the inflow occurs into the inclined intake region of the outlet opening.
In accordance with a further preferred embodiment of the invention, the mechanical seal arrangement further includes a second transition channel which extends in the circumferential direction, becomes continually deeper towards the outlet opening and is arranged on a side of the outlet opening opposite the first transition channel. As a result, a fluid supplied to the slide ring can be discharged more effectively independently of the direction of rotation. The two transition channels lie opposite each other at the outlet opening, and therefore an improved inflow into the outlet opening is achieved in each case independently of the direction of rotation. In a particularly preferred manner, the first and second transition channels are arranged symmetrically with respect to the outlet opening.
It is further preferred if the outlet opening comprises first and second intake regions which both open into a common main region. The first and second intake regions are arranged symmetrically with respect to a centre line of the main region. This design is likewise suitable, in a particularly preferred manner, for an inflow of fluid independently of the direction of rotation. The two intake regions are preferably formed symmetrically and each of the intake regions includes its own transition channel.
In a particularly preferred manner, the transition channel is formed such that a base of the transition channel lies in a plane. On the one hand, an effective inflow of the fluid to the outlet opening is hereby achieved and on the other hand the transition channel can be produced in a very simple and cost-effective manner, for example by means of a chip-removing method.
For improved flow, a transition region between the transition channel and the outlet opening is preferably formed as an arcuate deflection contour. A soft transition from the transition channel into the outlet opening can hereby be achieved.
It is further preferred if the mechanical seal arrangement includes precisely one outlet opening. Hereby, only precisely one outlet opening needs to be provided in the housing component in order for sufficient space to remain in the housing component for further elements and openings, e.g. for attaching the housing or additional fluid channels or the like.
Preferably, the outlet opening includes a main region and an intake region, wherein the intake region is arranged at an angle to the main region and centre axes of the main region and of the intake region lie in a common plane which is perpendicular to the longitudinal axis of the mechanical seal arrangement. Alternatively, the intake region can also be provided to be inclined, in the axial direction of the mechanical seal arrangement, with respect to the radially extending main region.
Preferred exemplified embodiments of the invention will be described in detail hereinafter with reference to the accompanying drawings. Like components, or components acting in a functionally identical manner, are designated by like reference numerals. In the drawing:
A mechanical seal arrangement 1 in accordance with a first exemplified embodiment of the invention will be described in detail hereinafter with reference to
As can be seen in
The stationary slide ring 4 is fixed to a housing component 6.
The rotating slide ring 3 is connected to a shaft 13 via an entrainment element 10. The entrainment element 10 thereby transfers a torque from the shaft 13 to the rotating slide ring 3.
Furthermore, an internal conveying device 11 having blades 12 is arranged on the shaft 13. The internal conveying device 11 rotates together with the shaft 13 and is used to convey a fluid to the mechanical seal 2. The fluid can be, for example, a sealing medium or a coolant. The fluid flow is designated in
An outlet opening 7 is also provided in the housing component 6. The outlet opening 7 is oriented in the radial direction Z-Z of the slide rings and is used to discharge the fluid. An inner, cylindrical peripheral region 60 is formed in this case on the housing component 6. The outlet opening 7 extends in this case radially outwards from the inner, cylindrical peripheral region 60. The outlet opening 7 is provided radially outside and over the rotating slide ring 3.
An inflow region 17 having an open transition channel 8 is also formed on the inner, cylindrical peripheral region 60 in the region of the outlet opening 7. The transition channel 8 can be seen in detail in
The transition channel 8 oriented in the circumferential direction thus allows improved inflow of the fluid into the outlet opening 7. In particular, the transition channel 8 allows a directed inflow of the fluid into the radial outlet opening 7, and therefore flow losses can be reduced. Therefore, a significant increase in the through-flow amount can be achieved with the outlet opening 7 having the same diameter by providing the transition channel 8, compared with an outlet opening which does not have a transition channel 8. Therefore, a conveying power can be increased with an identical conveying device 11, or an internal conveying device 11 can be provided with reduced conduction, whereby in particular an energy consumption of the internal conveying device 11 can be reduced.
In accordance with the invention, an increased volumetric flow of the fluid can therefore be achieved with otherwise identical dimensions, and therefore, for example, improved cooling of the mechanical seal 2 can be achieved. It is also possible in accordance with the invention for merely precisely one outlet opening 7 to be provided in the housing component 6, and therefore the remaining structural space in the housing component 6 can be used for other purposes, e.g. for providing further fluid channels and/or fastening elements or the like.
As can be seen in
Therefore, in the second exemplified embodiment, an improved incident flow to the radial outlet bore 7 can be obtained independently of the direction of rotation of the mechanical seal. The two transition channels 8, 9 are formed symmetrically with respect to the outlet opening 7.
The dotted lines in
The fifth exemplified embodiment shown in
It should be noted with respect to all the exemplified embodiments that in accordance with the invention a significantly improved flow of fluid from the slide rings into an outlet opening 7 can thus be achieved by providing one or more inflow regions 17 having transition channels 8, 9 in a cylindrical peripheral region 60. In particular, a sufficient mass flow of the fluid can be achieved by providing merely one single outlet opening 7. In particular, a housing structure of the housing component 6 can hereby be significantly simplified.
Number | Date | Country | Kind |
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10 2013 223 226.8 | Nov 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/072963 | 10/27/2014 | WO | 00 |