EP3472453A1 - Delivery pump for cryogenic fuels - Google Patents

Abstract

The invention relates to a delivery pump (10) for cryogenic fuels (1), comprising a pump casing (11) inside which a pump piston (25) is arranged in such a way as to be able to reciprocate within a pump chamber (30); the pump piston (25) is connected to a drive (40) for the pump piston (25) by means of a piston rod (26) which is radially guided within a longitudinal bore (20) in the pump casing (11) and which is sealed from the longitudinal bore (20) by at least one sealing device (60), said at least one sealing device (60) being designed to at least reduce leakage of fuel (1) from the pump casing (11).

Description

 description

Feed pump for cryogenic fuels

State of the art

The invention relates to a feed pump for cryogenic fuels according to the preamble of claim 1.

Such a feed pump is known from US Pat. No. 7,293,418 B2. The well-known pump is characterized by the fact that they partially in one

Tank container for the cryogenic fuel protrudes. For this purpose, the known feed pump passes through a wall of the tank. The outside of the

Tank container arranged drive the feed pump is exemplified by a hydraulic drive. This hydraulic drive acts on a pump piston connected to a piston rod, which on the suction side of the

Feed pump is disposed within the tank container. By means of the

Pump piston is the cryogenic fuel in a pump room of the

 Suction pump housing and then with a movement of the

Pump piston compressed in its other direction of movement and

For example, a heater supplied under pressure increase. The cryogenic fuel is, for example, natural gas that has been cooled within the tank to a temperature of, for example, less than -1 10 ° C so that the natural gas can be stored in liquid form in the tank.

Characteristic of such known from the prior art

Feed pumps is that the piston rod usually via one or more, arranged in the axial direction of the piston rod in a row

Sealing devices is sealed. These sealing devices are intended to prevent the fuel from escaping along the piston rod from the region of the delivery pump filled with the fuel. However, these sealing devices are also characterized by the fact that they are usually not 100% tight.

As a result, escapes fuel into the environment, either directly, or eg via the hydraulic circuit, which serves in the above-mentioned feed pump the drive of the feed pump. Since, due to legal requirements, the permissible amount of fuel that may reach the environment is limited, it is desirable to effect the best possible sealing of the piston rod to the pump housing, so that as little fuel as possible gets into the environment.

Disclosure of the invention

The feed pump for cryogenic fuels having the features of claim 1 has the advantage that an optimized sealing of the piston rod relative to the pump housing is achieved. As a result, the amount of fuel discharged via one or more sealing devices to the environment can be reduced or, in the best case, a complete sealing of the piston rod can be achieved, so that no fuel is released into the environment.

The invention is based on the idea of designing a sealing device in such a way that it encloses the piston rod at least indirectly, sealingly, on its outer circumference at an (end) region, wherein it is connected to the piston rod at its outer circumference. Thereby, a relative movement between the sealing device and the outer circumference of the piston rod is prevented, as would normally be present in the usual sealing devices in the form of O-rings or the like. This dense and firm installation of the sealing device is made possible by a bellows element whose not connected to the piston rod other (end) is in turn firmly and sealingly connected to the longitudinal bore, to there also a relative movement between the sealing device and the pump housing or the To avoid longitudinal drilling.

Advantageous developments of the feed pump according to the invention for cryogenic fuels are listed in the dependent claims.

In a particularly preferred constructional embodiment of the delivery pump, it is possible that vaporized fuel entering the bellows space via a seal from the pump chamber is returned to the inner tank can be, so that a pressure balance between the tank and the

Balgraum is made possible, it is provided that the bellows element of the sealing device within a bellows space of the longitudinal bore of the

Pump housing is arranged, and that the Balgraum over a

Connecting cable is connected to an inner tank.

In order to seal the piston rod against liquid fuel and thus form a further barrier to the fuel in the direction of the bellows element of the sealing device, it is provided that the piston rod on the piston chamber facing side with a further sealing element for

 Longitudinal bore is sealed off.

The sealing of the bellows element to the longitudinal bore or the bellows space on the outer diameter of the bellows element is preferably carried out by a

End portion of the bellows radially encompassing seal, for example in

Shape of a fixedly arranged O-ring.

In order to avoid that over the bellows space in the direction of the drive side, in particular in the direction of a hydraulic circuit, fuel passes, it is provided that in the axial direction of the bellows element on the

Compressor piston side facing away between the piston rod and the longitudinal bore a leakage chamber connects, which is vented to the environment.

To this leakage space on the one hand with respect to the bellows space, and on the other hand with respect to the hydraulic chamber or the hydraulic drive of the

 To seal the pump piston, it is provided that the leakage space is axially limited by two, the piston rod comprising additional sealing elements. To the movement of the flexible parts or areas of the bellows element at a

It is also advantageous if the interior of the bellows element communicates via a vent in the pump housing to the environment to prevent reciprocation of the piston rod. As bellows in particular membrane bellows or wave bellows come to

Application. Particularly preferred for forming a tight connection between the bellows member and the piston rod, moreover, when the bellows member is made of metal and with the outer periphery of the

Piston rod at one end portion is tightly welded. Such welding can be done for example via a laser beam device.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing.

This shows in:

Fig. 1 is a system view of a fuel delivery system with a

 Feed pump for cryogenic fuels and

Fig. 2 shows a portion of the feed pump of FIG. 1 in an enlarged

 Presentation.

The same elements or elements with the same function are provided in the figures with the same reference numerals.

1, a fuel delivery system 100 for cryogenic fuel 1 is shown. The fuel 1 is, in particular, natural gas and the fuel delivery system 100 is preferably used

Internal combustion engines of motor vehicles.

The fuel delivery system 100 has a tank container 5, which is the

Storage of the cooled down to a temperature of, for example -1 10 ° C or less fuel 1 is used. For this purpose, the tank container 5 an inner tank 6, of an outer shell 7 to form a

Interspace 8 is surrounded. The gap 8 is usually evacuated in order to prevent heat transfer or heat input from the environment into the cooled-down fuel 1. Within the tank 5, in particular within the inner tank 6, the liquid portion of the ranges

Fuel 1 to a filling level 9. Above the filling level 9, the fuel 1 is present in its gaseous phase. The tank container 5 or its inner tank 6 and the outer shell 7 is penetrated by a feed pump 10, which has a pump housing 1 1. The

Pump housing 1 1 is sealed relative to the tank container 5 in the region in which the pump housing 1 1 passes through the wall of the tank container 5. While the suction side of the feed pump 10 is within the

Tank container 5, in particular below the filling level 9, the pressure side of the feed pump 10 is connected outside of the feed pump 10 with a heater 15. The heater 15 is used in a conventional manner to heat the funded by the pump 10 with pressure increase from the tank tank 5 fuel 1, for example, to 60 ° C to him indirectly at least one gas valve (not shown) to supply, either a Intake tract of the internal combustion engine is assigned, or a single combustion chamber of the internal combustion engine.

The pump housing 1 1 has, for example, two housing parts 16, 17 which adjoin one another in the axial direction, wherein between the two

Housing parts 16, 17, for example, a seal 18 (Fig. 2) is arranged, which serves to seal the two housing parts 16, 17. In one housing part 16, which is partially disposed within the tank container 5 and partially outside of the tank 5, a longitudinal bore 20 with

Hole sections formed with different diameters. Within the longitudinal bore 20 along a longitudinal axis 21 of the longitudinal bore 20 in the direction of the double arrow 22 reciprocating pump piston 25 is arranged. The pump piston 25 is connected to a piston rod 26 which protrudes from the longitudinal bore 20 on the side facing the second housing part 17 and projects into a blind hole-shaped bore 27 of the second housing part 17. Within the bore 27 a connected to the piston rod 26 hydraulic piston 28 is arranged and guided longitudinally displaceable.

The pump piston 25 is arranged within the longitudinal bore 20 in a pump chamber 30. The pump chamber 30 has on the piston rod 26th

On the opposite side via a bore portion 31 of the longitudinal bore 20 connection with the fuel 1 in the inner tank 6. About the bore portion 31, fuel 1 is sucked from the inner tank 6 into the pump chamber 30. For this purpose, it is provided that in the region of the bore portion 31, a suction valve 32 is arranged in the form of a check valve, which is an ejection of fuel 1 prevented from the pump chamber 30 in the direction of the inner tank 6. Furthermore, near the bore portion 31 in the pump housing is a

High-pressure bore 33 formed on the pump chamber 30th

opposite side is connected to the heater 15. In the area of the pump chamber 30, the high-pressure bore 33 has a high-pressure valve 35, which on the one hand, a return flow of fuel 1 from the region of

High-pressure bore 33 in the pump chamber 30 during a suction movement of the pump piston 25 prevents, and on the other hand opens when ejecting fuel 1 from the pump chamber 30 into the high pressure bore 33 from a certain pressure.

The drive of the pump piston 25 via the hydraulic piston 28, which is part of a hydraulic drive 40 of the feed pump 10.

In addition it is mentioned that in modification of the shown

Embodiment, the movement of the pump piston 25 and the drive of the pump 10 can also be done via a pneumatic, electric or other drive. It is only essential that the pump piston 25 is arranged back and forth via the piston rod 26 corresponding to the double arrow 22.

The hydraulic drive 40 also has, in a known manner, a first switching valve 41 for filling or controlling hydraulic fluid in the direction of two subspaces 43, 44 of the bore 27, the one

Hydraulic piston chamber 45 forms. The first switching valve 41 is part of a hydraulic circuit, which also has a second switching valve 46, a hydraulic pump 47, a radiator 48, a filter 49 and a

Hydraulic tank 50 includes. By the hydraulic actuators 40 and the enumerated elements is reciprocated in the known manner of the hydraulic piston 28 and thus also via the piston rod 26 of the compressor piston 25 in the direction of the double arrow 22.

As can be seen in particular with reference to FIG. 2, the piston rod 26 is sealed within the longitudinal bore 20 of the first housing part 16 at least by means of three hydraulic seals 51 to 53 relative to the longitudinal bore 20. The two hydraulic seals 51, 52 which are axially in relation to Longitudinal axis 21 are arranged spaced from each other, are arranged within a portion of the longitudinal bore 20, which forms a leakage space 55. The leakage chamber 55 is connected via a vent hole 56 with the environment. On the other hand, the third hydraulic seal 53 is arranged on the side facing the pump piston 25 and axially delimits one

Section of the longitudinal bore 20, which forms a bellows space 58. Near the hydraulic seal 53 opens a connecting hole 59 which connects the bellows space 58 with a region of the inner tank 6, which is arranged above the filling level 9. As a result, constituents of the fuel 1, which pass through the hydraulic seal 53 into the bellows space 58 and evaporate there, can be returned to the inner tank 6 via the connection bore 59. As a result, we also allows pressure equalization between the bellows space 58 and the inner tank 6. Within the bellows space 58, a sealing device 60 in the form of a bellows element 61 is arranged.

The bellows member 61 is formed either as a diaphragm bellows or corrugated bellows and is preferably made of metal. The bellows element 61 has a first end region 62 which surrounds the outer circumference of the piston rod 26 on the side facing the pump piston 25. In particular, the first end region 62 of the bellows element 61 is tightly and firmly connected to the outer circumference of the piston rod 26, for example by a radially encircling one

Weld 63. The bellows 61 also has on the

Hydraulic piston 28 side facing a second end portion 64 which has a radially circumferential groove 65. In the groove 65, a sealing element is arranged, for example in the form of an O-ring 66, the second end portion 64 of the

Balgelements 61 seals to the wall of the bellows space 58 and thus to the longitudinal bore 20. The interior 67 of the bellows member 61 is connected via a formed in the first housing part 16 bore 68, for example, with the environment.

Due to the tight and firm connection of the first end portion 62 of the

Balgelements 61 with the outer circumference of the piston rod 26 in the bellows space 58 and the sealed arrangement of the second end portion 64 to

Longitudinal bore 20, a seal of the bellows space 58 is achieved in the direction of the hydraulic piston 28 and the environment. This can also over the

Connecting bore 59 or via the hydraulic seal 53 in the bellows 58th entering fuel 1 does not enter the environment, but remains in the bellows space 58th

The delivery pump 10 described so far can be modified or modified in many ways, without departing from the spirit.

Claims

claims

1 . Feed pump (10) for cryogenic fuels (1), comprising a pump housing (1 1), in which a pump piston (25) within a pump chamber (30) is arranged back and forth, wherein the pump piston (25) by means of a piston rod (26 ) is connected to a drive (40) for the pump piston (25), wherein the piston rod (26) within a longitudinal bore (20) of the pump housing (1 1) guided radially and by means of at least one sealing device (60) to the longitudinal bore (20) is sealed, wherein the at least one sealing means (60) is adapted to at least reduce a leakage of fuel (1) from the pump housing (1 1), characterized in that the at least one sealing means (60) comprises a bellows member (61) , which at a first region (62) sealingly surrounds the piston rod (26) at its outer circumference and is at least indirectly fixedly connected to the outer circumference, that the bellows element (61) at a second region (64) on an Au ßendurchmesser to the longitudinal bore (20) towards sealed and to the longitudinal bore (20) is fixedly connected, and that the first and he second region (62, 64) are preferably axial end portions of the bellows element (61).

2. Feed pump according to claim 1,

 characterized,

 that the bellows element (61) within a bellows space (58) of the

 Longitudinal bore (20) is arranged, and that the bellows space (58) for

 Pressure equalization with a connecting line (59) with an inner tank (6) is coupled.

3. Feed pump according to claim 1 or 2,

 characterized,

in that the pump chamber (30) can be supplied with substantially liquid fuel (1), and in that the piston rod (26) is mounted on the pump chamber (30) facing side with a sealing element (53) to the longitudinal bore (26) is sealed off.

4. Feed pump according to one of claims 1 to 3,

 characterized,

 in that the second region (64) of the bellows element (61) is sealed to the longitudinal bore (20) by means of a seal which radially surrounds the second region (64), for example in the form of a fixedly arranged O-ring (66).

5. Feed pump according to one of claims 1 to 4,

 characterized,

 that in the axial direction of the bellows element (61) on the

 Pump piston (25) facing away between the piston rod (26) and the longitudinal bore (20) a leakage chamber (55) connects, which is vented to the environment.

6. Feed pump according to claim 5,

 characterized,

 in that the leakage space (55) is delimited axially by two additional sealing elements (51, 52) which surround the piston rod (26) on its circumference.

7. Feed pump according to one of claims 1 to 6,

 characterized,

 the interior (67) of the bellows element (61) has a connection to the environment via a vent (68) in the pump housing (11).

8. Feed pump according to one of claims 1 to 7,

 characterized,

 the piston rod (26) is connected on the side facing away from the pump piston (25) to a hydraulic piston (28) as part of a hydraulic drive (40) of the feed pump (10).

9. Feed pump according to one of claims 1 to 8,

 characterized,

the bellows element (61) is designed as a diaphragm bellows or corrugated bellows.

10. Feed pump according to one of claims 1 to 9,

characterized,

in that the bellows element (61) consists of metal and with the outer circumference of the piston rod (26) at the one region (62) by means of its weld seam

(63) is tightly welded.