EP3299630A1 - Compressor assembly - Google Patents

Abstract

The invention relates to an arrangement (A) for compressing a process fluid (PF) with a drive (DR) and a multistage transmission compressor (GVT), the drive (DR) being mechanically drivable by means of a first clutch (CP1) with the transmission compressor (GVT) is connected, characterized in that the drive (DR) by means of a second clutch (CP2) is directly or indirectly mechanically driven with a separate compressor (CMP), wherein the separate single compressor (CMP) is arranged upstream of the transmission compressor (GVT) in that the separate single compressor (CMP) draws in and compresses the process fluid (PF) and at least in part conveys downstream to a first stage (SG1) of the gear compressor (GVT) by means of a connection line (CD1) of the assembly (A).

Description

The invention relates to an arrangement for compressing a process fluid with a drive and a multi-stage gear compressor, wherein the drive is mechanically drivingly connected by means of a first clutch with the gear compressor.

Arrangements with a gear compressor or gear compressor are already out of the DE102010020145-A1 . DE102009015862-A1 . DE102014225136-A1 . DE102015200439-A1 . DE102015203287-A1 known.

• ein Getriebegehäuse
• eine Antriebswelle
• mehrere Radialfluidenergiemaschinen,
• ein Getriebe in dem Getriebegehäuse, das mehrere Ritzelwellen aufweist, wobei die mehreren Radialfluidenergiemaschinen von den mehreren Ritzelwellen angetrieben werden, wobei die mehreren Radialfluidenergiemaschinen außen an dem Getriebegehäuse angeordnet sind.

A transmission compressor of an arrangement according to the invention generally comprises:

• a gearbox
• a drive shaft
• several radial fluid energy machines,
• a transmission in the transmission housing having a plurality of pinion shafts, wherein the plurality of radial fluid power machines are driven by the plurality of pinion shafts, wherein the plurality of radial fluid power machines are disposed outside of the transmission housing.

The known gear compressor are used for the compression of large volume flows, in particular for the air compression. As the size increases, the space required for the radial fluid energy machines or the compressor stages-arranged on the transmission housing of the transmission compressor-also increases. This results in collision problems of the housing of the radial fluid energy machines, which are also referred to as spiral housing. Regularly, the distance of the arranged on the gearbox volute casing is limited due to internal gear design conditions. With reasonable constructive effort this distance can hardly be increased. The usually used in the transmission Large wheel is chosen so large in diameter that the distance between the pinion shafts to drive the radial turbofan energy machines is sufficient. For strength mechanical reasons, the enlargement of the large wheel has limits, because the outer peripheral speed can not be increased without limit. For the same reasons, the speed of the radial fluid power machines or the drive speed can not be increased without limit. Accordingly, results for a given gear design in the gearbox of the gear compressor, an upper size barrier, which can not be broken with previous means.

Based on the problems and disadvantages of the prior art, the invention has the object to develop an arrangement of the type defined in such a way that even larger volume flows of process gas can be compressed.

To solve the object of the invention, an arrangement of the type defined above is proposed with the additional features of the characterizing part of the independent claim. The respective dependent claims contain advantageous developments of the invention.

A preferred embodiment of the transmission compressor of the arrangement according to the invention provides that the transmission comprises a large wheel, wherein the large gear and the drive shaft have a common first axis of rotation, wherein an external toothing of the large wheel drives directly or indirectly pinion shafts of the radial fluid energy machines. Furthermore, it is expedient according to the invention if the radial fluid power machines are compressor stages.

A preferred field of application for the arrangement according to the invention is the air separation. The efficiency of the compression has a high priority in the air separation. The mechanical losses in gearbox compressors are mainly ventilation losses in the gearboxes. The gas volume trapped in the gears is swirled by the intermeshing gears and heats up significantly in this lossy flow. Accordingly, it is desirable to design the smallest possible transmission with a small pitch circle speed. With the arrangement according to the invention, the gear size of the gear compressor can be reduced as a result of the outsourcing of the first compression stage, without causing collisions of the spiral housing. In this way, there are improvements in efficiency of the transmission compressor as a result of the invention.

High powers to be transmitted in the gearbox of the gear compressor large tooth widths of the gear wheels are necessary. The oil lubricating the gears heats up significantly more as a result of the increased squeezing oil losses due to the increased width. The heating must be cooled by means of a cooling system, so that there is no destruction (cracking) of the oil. The invention also reduces this problem by means of the outsourcing of the first compression stage, so that the transmission of the gear compressor must transmit only a lower power.

The invention results in a further degree of freedom of design because the gear compressor can on the one hand be designed as a standard component and the separate individual compressor can be adapted to the prevailing ambient pressure of the installation site. The adaptation of the upstream of the gear compressor arranged single compressor is less expensive. The final pressure of the compressor is highly dependent on the ambient pressure, so that the simple possibility of adaptation by means of the arrangement according to the invention is desirable.

An advantageous development of the invention provides that the process fluid from the separate single compressor completely is forwarded to the first stage of the transmission compressor by means of the connecting line. A complete redirection is to be understood as forwarding minus any losses (eg leaks). In principle, it is also possible that only a partial forwarding takes place, for example, if the separate compressor does not take over the pre-compression not only for a single transmission compressor. The separate single compressor can be suitably designed as a large blower, as axial compressor or as a radial compressor.

A particularly preferred solution according to the invention provides that the gear compressor has a drive shaft to which at one end of the shaft, the first clutch and at the other end of the shaft, the second clutch are arranged so that the drive shaft is formed as a drive through the gear compressor. The word "through drive" means that a shaft of the gear compressor driven by the drive extends through the gearbox of the gear compressor, so that a direct or indirect coupling of the separate single compressor can take place by means of the second clutch. An indirect coupling of the separate single compressor is conceivable, for example, by providing an intermediate gear. In principle, it is also possible for a through drive to be provided by the transmission of the transmission compressor, wherein this through drive provides for a change in the rotational speed from the drive to the separate separate compressor in the transmission of the transmission compressor. For example, the separate single compressor may be coupled directly or indirectly to a pinion shaft of the gear compressor.

An alternative to a drive through the gearbox of the gear compressor is the ability to provide the drive between the separate single compressor and the gear compressor, so that a motor shaft extends through the drive and is coupled to a shaft end by means of a first clutch of the gear compressor and on the other shaft end of the motor shaft is coupled to transmit power by means of a second clutch of the separate single compressor.

The separate individual compressor particularly preferably has a pressure ratio of between 2 and 3. In this connection, an advantageous development provides that the entire arrangement has a pressure ratio between 4 and 600. Here, the transmission compressor may expediently have a pressure ratio between 2-200. The gear compressor is designed with up to 8 stages. The gear compressor may each have an intermediate cooling between the individual compression stages. It is particularly advantageous to provide intermediate cooling between the individual compressor and the transmission compressor. An advantageous development provides that the individual compressor has only a single stage or a single impeller of a centrifugal compressor.

According to the invention, the individual compressor can be structurally given an adapted speed by means of a variation of the number of teeth of a first gear, which can be advantageously assigned to the individual compressor for the transformation of the drive speed to the compressor speed. For this purpose, it is advantageous in the sense of standardization if the individual compressor has adjustable bearing points, so that the speed adaptation does not require a complicated adaptation design.

Figuren 1, 2, 3

jeweils eine schematische Wiedergabe einer erfindungsgemäßen Anordnung.

In the following the invention with reference to a specific embodiment with reference to drawings is described in more detail. Show it:

FIGS. 1, 2, 3

in each case a schematic representation of an arrangement according to the invention.

The FIGS. 1 . 2 and 3 each show an inventive arrangement A in a schematic plan view. In each of these examples, the compression of a process fluid PF in five consecutive stages ST1, ST2, ST3, ST4, ST5. The entire arrangement is driven by means of a drive DR, which is preferably designed as a four-pole or six-pole electric motor. The drive DR is mechanically drivingly connected to the transmission compressor GVT by means of a first clutch CP1. By means of a second clutch CP2, the drive DR is indirectly or directly mechanically connected to a separate single compressor CMP. The separate single compressor CMP is arranged upstream of the transmission compressor GVT such that the process fluid PF is forwarded downstream to the first stage SG1 of the transmission compressor via a connection line CD1. Optionally, a first intermediate cooling IC1 may be provided in the connecting line CD1 for removing a first heat flow Q1 ( FIG. 1 ). The first stage SG1 of the transmission compressor GVT is at the same time the second stage ST2 of the entire compression process. The gear compressor GVT itself has four compression stages and, based on the overall process, these stages include the second compression stage ST2, the third compression stage ST3, the fourth compression stage ST4 and the fifth compression stage ST5. Particularly preferably, an intermediate cooling can be provided between each compression stage of the transmission compressor GVT, in which FIG. 1 For this purpose, in each case between the stages ST2, ST3, ST4, ST5 a second, third and fourth intermediate cooling IC2, IC3, IC4 provided for discharging a second, third and fourth heat flow Q2, Q3, Q4.

In the FIG. 1 the special embodiment of a drive through the drive DR is shown, in which a motor shaft MSH carries the first clutch CP1 with a first end and the second clutch CP2 with a second end. Accordingly, the separate single compressor CMP is arranged at the first end of the motor shaft MSH and the gear compressor GVT is connected to the second clutch CP2. The motor shaft MSH extends through the drive DR in the sense of a through drive, wherein the drive DR between the transmission compressor GVT and the separate single compressor CMP is arranged.

The single compressor CMP has a first transmission GE1. The transmission compressor has a second transmission GE2. Like in the FIG. 3 illustrated, the first transmission 1 may also be formed integrated into the second transmission GE2. The individual compressor can constructively by means of a variation of the number of teeth of the first transmission GE1, which is advantageously assigned to the individual compressor CMP for the transformation of the input speed to the compressor speed, an adapted speed can be awarded. For this purpose, it is advantageous in terms of standardization if the individual compressor CMP has adjustable bearing points, so that the speed adaptation does not require a complicated adaptation design.

The lines for the process fluid PF are exemplified only at the gear compressor GVT in FIG FIG. 1 drawn in the others Figures 2 . 3 the detail has been omitted for simplicity.

As an alternative to this shows the FIG. 2 a drive through the gear compressor GVT. The gear compressor GVT in this case has a drive shaft DRS, at which at one end of the shaft, the first clutch CP1 and at the other end of the shaft, the second clutch CP2 are arranged. Accordingly drives the drive shaft DRS of the gear compressor GVT as a through drive the separate single compressor CMP.

An advantageous development of this shows the FIG. 3 , in which the gear compressor GVT is also arranged as a through drive between the separate single compressor CMP and the drive DR. Unlike in the FIG. 2 Here, the transmission of the gear compressor GVT is not only provided for the translation of the speed of the drive for the stages two to five, but it is in the gear compressor GVT also a translation of the rotational speed of the drive DR to a speed the separate single compressor CMP provided. Accordingly, an intermediate gear between the drive DR and the separate single compressor CMP is installed as an integrated component in the gear box of the gear compressor GVT. This intermediate gear can also be provided as a separate module between the gear compressor GVT and the separate single compressor CMP or as an integrated transmission component of the separate single compressor CMP, as in the FIG. 1 shown.

Claims (7)

Arrangement (A) for compressing a process fluid (PF) with a drive (DR) and a multistage transmission compressor (GVT),
wherein the drive (DR) is mechanically drivingly connected to the transmission compressor (GVT) by means of a first clutch (CP1),
characterized in that
the drive (DR) by means of a second clutch (CP2) is mechanically or indirectly directly or indirectly connected to a separate single compressor (CMP),
wherein the separate single compressor (CMP) is located upstream of the gear compressor (GVT) such that the separate single compressor (CMP) compresses the process fluid (PF) and downstream at least in part to a first stage (SG1) of the gear compressor (GVT) by means of a connection line (CD1) the arrangement (A) passes. Arrangement (A) according to claim 1,
wherein the separate single compressor (CMP) forwards the process fluid (PF) completely to the first stage (SG1) of the transmission compressor (GVT) by means of the connection line (CD1). Arrangement (A) according to claim 1,
wherein the transmission compressor (GVT) has a drive shaft (DRS), at one end of the shaft, the first clutch (CP1) and at the other end of the shaft, the second clutch (CP2) are arranged, so that the drive shaft (DRS) as a drive through the transmission compressor (GVT) is formed. Arrangement (A) according to claim 3,
wherein the transmission compressor (GVT) comprises a first transmission (GE1) as an integral part for changing the drive speed of the drive (DR) to a speed of the individual compressor (CMP), so that the transmission compressor (GVT) in addition to a second transmission (GE2) for driving the steps (ST2-ST5) of the transmission compressor (GVT) also has a first transmission (GE2). Arrangement (A) according to claim 1,
the drive (DR) being arranged between the transmission compressor (GVT) and the separate separate compressor (CMP), the drive (DR) having a motor shaft (MSH), a first end of the motor shaft (MSH) being the first clutch (CP1) carries, wherein a second end of the motor shaft (MSH) carries the second clutch (CP2). Arrangement (A) according to at least one of the preceding claims 1 to 3,
wherein the separate single compressor (CMP) has a pressure ratio between 2-3. Arrangement (A) according to at least claim 1 or 5,
wherein the entire assembly (A) has a total pressure ratio of 4.0 to 70.

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