SEALING JOINT FOR A COMPRESSOR CASING |
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申请号 | US14413163 | 申请日 | 2013-07-08 | 公开(公告)号 | US20150198170A1 | 公开(公告)日 | 2015-07-16 |
申请人 | TRANE INTERNATIONAL INC.; | 发明人 | Mark W. Harrison; | ||||
摘要 | A sealing joint for a compressor casing, such as a compressor casing for a centrifugal compressor of a chiller, is provided. The sealing joint may be configured to have a first cover and a second cover. A first mating surface of the first cover may have an inner annular portion surrounding an inner cavity of the sealing joint, and an outer annular portion. The inner annular portion may be positioned between the inner cavity of the compressor casing and the outer annular portion. A sealant may be applied to the sealing joint, and a depth of the sealant on the inner annular portion may be deeper than a depth of the sealant on the outer annular portion. The depth of the sealant on the inner annular portion may help the sealing joint tolerate more elongation range without a sealant failure than a regular casing. | ||||||
权利要求 | |||||||
说明书全文 | Embodiments disclosed herein relate generally to a compressor of a heating, ventilation and air conditioning (HVAC) system. More specifically, the embodiments disclosed herein relate to a sealing joint for a compressor casing, such as a casing for a centrifugal compressor of a chiller. A HVAC system, for example a chiller with shell and tube heat exchangers, sometimes uses a centrifugal compressor. The centrifugal compressor generally includes a motor configured to drive one or more impellers, and the compressor may be housed in a compressor casing. During operation, refrigerant can be sucked into the compressor casing and compressed by a centrifugal force, thus creating a relatively high pressure inside the compressor casing. In some situations, the compressor casing may be configured to include two separate covers that are jointed together by a mounting mechanism, such as bolts and nuts so that the compressor casing can be opened, for example for service purposes. The embodiments disclosed herein relate to a sealing joint for a casing, such as a casing for a centrifugal compressor of a chiller. In some embodiments, the sealing joint may include two covers that may be configured to withstand a pressure of compressed refrigerant and seal the refrigerant inside the compressor casing. In some embodiments, a sealant, such as a Loctite® anaerobic sealant may be applied to the sealing joint to form a sealant layer to help seal the refrigerant inside the compressor casing. An interface of a sealing joint of a compressor subject to a pressure may separate due to the pressure or other applications, which may cause elongation of the sealant applied to the interface. When the elongation of the sealant layer exceeds a tolerable elongation range of the sealant layer, the sealant layer may fail, causing refrigerant leakage from the sealing joint. In some embodiments, the sealing joint may be configured to include a first cover and a second cover, which has a first mating surface and a second mating surface respectively. In some embodiments, the first mating surface may be configured to have a first portion and a second portion. In some embodiments, the first portion and the second portion may be configured to form the sealing joint with the second mating surface. In some embodiments, the first cover and the second cover may be configured to be mounted together by a mounting mechanism, such as a plurality of bolts and/or nuts, etc. In some embodiments, the first portion of the first mating surface is configured to accommodate the mounting mechanism. In some embodiments, the sealing joint has an inner cavity, and the second portion may be positioned between the inner cavity of the sealing joint and the first portion. In some embodiments, from a sectional view of the sealing joint, a step is formed between the first portion and the second portion. In some embodiments, the first portion and the second portion of the sealing joint may be configured to receive a sealant. In some embodiments, a depth of the sealant layer disposed on the second portion may be deeper than a depth of the sealant layer disposed on the first portion. In some embodiments, the first portion and the second portion are configured to encircle the entire inner cavity of the sealing joint. Other features and aspects of the embodiments will become apparent by consideration of the following detailed description and accompanying drawings. The embodiments disclosed herein relate to a sealing joint for a casing, such as a casing for a centrifugal compressor of a chiller. In a HVAC system that utilizes a centrifugal compressor, an impeller(s) of the centrifugal compressor is often housed in a compressor casing. The compressor casing can be configured to withstand a pressure created by compressed refrigerant. The compressor casing can be configured to have two separate covers that meet to form a sealing joint. A sealant, such as Loctite® anaerobic sealant, can be applied to an interface of the sealing joint to create a seal to prevent leakage of refrigerant at the sealing joint. During operation, the pressure inside the compressor casing sometimes can push the two covers apart at the sealing joint. Generally, the higher the pressure is, the further apart the two covers can be pushed, causing the sealant disposed on the interface to elongate. Since the sealant may generally have some flexibility, the sealant may be able to withstand some elongation created by the separation of the two covers under the pressure. However, when the separation of the two covers exceeds a tolerable elongation range of the sealant, the sealant may fail resulting in a leakage of refrigerant from the compressor casing. For example, when the compressor casing undergoes a factory pressure proof testing, the elevated pressure applied during the proof testing may separate the two covers apart beyond the tolerable elongation range of the sealant, causing the sealant to fail and thus the refrigerant to leak. In addition, some refrigerants may require an elevated working pressure inside the compressor casing, which may cause the sealant to fail. For example, when a chiller system is retrofitted to work with a different refrigerant, the newly applied refrigerant may work at a higher pressure than the previous refrigerant. The sealant of the retrofitted compressor therefore may have to withstand the higher working pressure without causing refrigerant leakage. Different sealants may have different predetermined tolerable elongation ranges. For example, based on the manufacturing recommendation, one of the Loctite® sealants has a tolerable elongation range of about 10% to 30% of a depth of the sealant layer. That is, the sealant layer may fail if the elongation of the sealant exceeds about 10 to 30% of the depth of the sealant layer applied to the interface of the joint. For example, in one application, the depth of the sealant layer applied on the interface of the sealing joint is about 0.001 inch. Based on the recommended tolerable elongation range of about 10 to 30% of the sealant layer's depth, the permitted elongation range can be set at about 20% of the depth of the sealant layer. For example, the sealant may fail under a pressure inside the compressor casing that can create a separation of the two covers exceeding about 0.0012 inch ((100%+20%)×0.001 inch of the depth) at the interface. Therefore if the compressor casing needs to withstand a higher pressure or reduce sealant failure rate under an elevated pressure, the applied depth of the sealant layer on the interface may have to be increased so as to increase the tolerable elongation range of the sealant on the interface. However, increasing the depth of the sealant layer applied on the interface may interfere with a hardening process of the sealant, i.e. the sealant may take longer to cure or may not cure at all without an accelerator. Using the accelerator may result in increased brittleness of the sealant, reducing the effectiveness of the sealant. For the Loctite® sealants described herein, the manufacturer recommends about 0.002 to 0.004 inch of the depth of the sealant layer. A sealing joint of a compressor casing, such as a centrifugal compressor of a chiller, is described herein. The sealing joint may be configured to have a first cover and a second cover. A first mating surface of the first cover may have an inner annular portion surrounding an inner cavity of the sealing joint, and an outer annular portion. The inner annular portion may be positioned between the inner cavity of the compressor casing and the outer annular portion. The inner annular portion and the outer annular portion may be configured to receive a sealant, and a depth of the sealant layer disposed on the inner annular portion may be deeper than a depth of the sealant layer disposed on the outer annular portion. The depth of the sealant layer on the annular portion may allow the sealant to tolerate a certain degree of elongation without sealant failure. References are made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration of the embodiments in which the embodiments may be practiced. It is to be understood that the terms used herein are for the purpose of describing the figures and embodiments and should not be regarded as limiting the scope of the present application. A front view of a portion of the first mating surface 255 of the first cover 251 is illustrated in It is to be appreciated that the mounting holes 270, configured to accommodate the plurality of bolts 260 and/or plurality of nuts 261, may be a part of a mounting mechanism to mount the first and second covers 251 and 252 together. In some embodiments, other types of mounting mechanisms may be used. For example, the second cover 252 may include threaded holes to catch the bolts 260 so that nuts are not necessary. In some embodiments, the outer annular portion 266 can be configured to accommodate the mounting mechanism. As illustrated in The step 272 is configured to be relatively close to the mounting holes 270 of the outer annular portion 266, as illustrated in In operation, the casing 117 is subject to a pressure due to compression of the refrigerant or due to other applications such as pressure proof testing. The pressure can push the first cover 251 and the second cover 252 apart so as to push the first mating surface 255 away from the second mating surface 256. The sealant 280 therefore is subject to elongation. The sealant 280 may have some flexibility. However, if the elongation of the sealant 280 exceeds a tolerable elongation range, the sealant may fail. The tolerable elongation range of the sealant 280 can be expressed as a percentage of the depth of the sealant layer 280. For example, for a Loctite® sealant, the tolerable elongation range of the sealant is about 20% of the depth of the sealant. If such a sealant is applied to the illustrated embodiment, the sealant layer 280 between the inner annular portion 265 and the second mating surface 256 may fail if the elongation of the sealant layer 280 exceeds about 20% of D2. However, since D2=D1+W, the sealant layer 280 between the inner annular portion 265 and the second mating surface 256 can tolerate more elongation than the sealant layer 280 between the outer annular portion 266 and the second mating surface 256. The width W can be configured so that the tolerable elongation range of the sealant layer 280 of the depth D2 (D2=D1+W) is larger than a maximum separation that the two covers 251 and 252 are subjected to during a normal operation and/or during other applications such as pressure proof tests. This maximum separation can be determined based on the separation caused by the operation pressure and/or pressure proof tests. Thus, the sealant layer 280 in the inner annular portion 265 can help ensure effective sealing between the first cover 251 and the second cover 252 even when the casing 117 is subjected to the maximum separation. A conventional casing of two planar mating surfaces without the step 272 generally has a sealant layer depth of D1. The sealant layer depth D1 may be generally determined by, for example, a torque of the bolt 260 and the nut 261. Different from conventional casings, because D2 is generally larger than D1, the sealing joint 250 of the casing 117 as illustrated in In one particular embodiment, when installed, the Loctite® sealant between the outer annular portion 266 and the second mating surface 256 is about 0.001 inch (i.e. D1=0.001 inch). The width W for the step 272 is about 0.003 inch. Therefore, the depth D2 (=D1+W) is about 0.004 inch. The Loctite® sealant has a tolerable elongation range of 20% of the depth of the sealant layer, which is determined based on the manufacturer's recommendation. Accordingly, the casing 117 can tolerate up to 0.0008 inch of separation without the sealant layer 280 failing at the sealing joint 250. In a conventional casing, which has a sealant layer depth of about 0.001 inch, the casing may fail if the separation is more than about 0.0002 inch (20% of 0.001 inch). Thus, compared to a conventional casing, the casing 117 (and the sealant 280) can tolerate about 0.0006 inch more of separation (or sealant elongation). In operation, a sealant 380 can be applied to the mating surfaces 355 and 356. Because the protrusion ring 390 provides the depth D3, the casing 317 can help increase a depth of the sealant layer 380 relative to the depth of the sealing layer between the protrusion ring 390 and the second mating surface 356. It is to be noted that the embodiments described here are exemplary. In the illustrated embodiments, only one mating surface is configured to have surface features, such as the step 272 and/or the surface protrusion(s), to increase the depth of the sealant layer on the mating surfaces. In some other embodiments, both of the mating surfaces can have surface features to increase the depth of the sealant layer. The annular portion for the embodiments as shown in It is to be appreciated that different sealants may have different tolerable elongation ranges. The tolerance range may generally be specified by manufacturers. Depending on the sealant applied, the width of the step (e.g. the width W of the step 272 in Any aspects 1-6 can be combined with any aspects 7-14. Any aspects 7-9 can be combined with any aspects 10-14. Any aspects 10-12 can be combined with any aspects 13-14. Aspect 1. A sealing joint for a compressor casing comprising:
Aspect 2. The sealing joint of aspect 1, wherein the first portion and the second portion are configured to receive a sealant. Aspect 3. The sealing joint of aspects 1-2, wherein the first portion and the second portion are configured to encircle the entire inner cavity of the sealing joint. Aspect 4. The sealing joint of aspects 1-3, further comprising:
Aspect 5. The sealing joint of aspect 4, wherein the second mating surface is planar. Aspect 6. The sealing joint of aspects 1-5, wherein the first portion of the mating surface has a hole to accommodate a mounting mechanism. Aspect 7. A sealing joint of a compressor casing comprising:
Aspect 8. The sealing joint of aspect 7, wherein the first mating surface and the second mating surface are configured such that when they are subjected to a maximum separation, and where the sealant has a recommended elongation range relative to a depth of the sealant on the second portion of the first mating surface, the maximum separation is less than the recommended elongation range. Aspect 9. The sealing joint of aspects 7-8, wherein the first portion and the second portion are configured to encircle the entire inner cavity of the sealing joint. Aspect 10. A sealing joint of a compressor casing, comprising:
Aspect 11. The sealing joint of aspect 10, further comprising:
Aspect 12. The sealing joint of aspects 10-11, further comprising:
Aspect 13. A method to increase a reliability of a sealing joint of a compressor casing, comprising:
Aspect 14. The method of aspect 13, wherein the second portion of the mating surface is positioned between an inner cavity of the sealing joint and the first portion of the mating surface. With regard to the foregoing description, it is to be understood that changes may be made in detail, especially in matters of the construction materials employed and the shape, size and arrangement of the parts without departing from the scope of the present invention. It is intended that the specification and depicted embodiment to be considered exemplary only, with a true scope and spirit of the invention being indicated by the broad meaning of the claims. |