DE102017208276A1 - Delivery unit for gaseous media - Google Patents

Abstract

The invention relates to a delivery unit (10) in which a first gaseous medium (30) promotes a second gaseous medium (38). The delivery unit (10) comprises a housing (11) in which a magnetic circuit (18) with an actuator (22) is accommodated. A mixing section (40), in which the gaseous media (30, 38) mix, is continuously adjustable between a first mixing section length (42) and a second mixing section length (44).

Description

Technical area

The invention relates to a delivery unit for conveying gaseous media, such as hydrogen in fuel cell systems. The invention further relates to the use of the delivery units.

State of the art

Out US 7,687,171 B2 For example, there is known a multi-stage ejector for a fuel cell system comprising at least one ejector main body for providing hydrogen, each of the ejector bodies comprising a number of nozzles arranged one behind the other leaving predetermined gaps whose diameters increase at the respective nozzles seen from an inlet side of the Ejektorhauptkörpers to an outward side thereof. Further, a number of sub inlets are formed on an outer surface of the ejector main body connected to the gap or the gaps between the individual nozzles. In a housing, the ejector main body is received and includes a main inlet for receiving recirculated hydrogen. The multi-stage ejector improves system performance by increasing the amount of recirculated hydrogen. Furthermore, at least one safety valve is provided at an inlet position of the ejector to definitely prevent the recirculated hydrogen gas from returning. At least one heater is provided which extends around the ejector to improve the cold start capability.

US 8,999,593 B2 refers to an ejector for a fuel cell. The ejector is used on a fuel cell and includes an ejector main body having an inlet port, an outlet port, a suction port, and an oxidizing gas port. Further, three chambers are provided in the body, and a nozzle having a nozzle hole through which the fuel gas flows, and a diffuser which mixes the fuel gas supplied through the nozzle and the gas discharged from the fuel cell and returns to the suction port. Further, a needle-shaped member is received on one side of the body, which extends axially along the nozzle in a space provided in this cavity. There are a first and a second diaphragm disposed opposite each other.

Disclosure of the invention

According to the invention, a delivery unit is proposed in which a first gaseous medium promotes a second gaseous medium; Furthermore, the delivery unit comprises a housing in which a magnetic circuit is received with an actuator. A mixing section of the delivery unit, in which the gaseous media mix, is infinitely adjustable within an adjustment range between a first mixing section length and a second mixing section length. Due to the stepless adjustability of the mixing section can be achieved in an advantageous manner that negative flow effects such as vertical shocks of the gaseous media are prevented, otherwise the flow rate of the gaseous medium to be conveyed would be reduced when they occur.

In a further advantageous embodiment of the delivery unit proposed according to the invention, the mixing section is formed by a housing part and a tubular extension formed thereon on the one hand and by a relative thereto movable armature part on the other.

If the actuator is designed as an electromagnet within a magnetic circuit, then the armature part can be infinitely adjusted in the axial direction, in accordance with the energization of the magnet coil. Thus, in particular the operating conditions of the pumping unit proposed according to the invention can be borne in partial load operation. While in the full load operation, on which the delivery unit is designed, a short mixing zone is required, in contrast, an extended mixing zone is required in partial load operation of the delivery unit.

Advantageously, the anchor member is acted upon by a spring which is supported on a press-fit. When the actuator is not energized, the armature part is set against the press-in ring by the spring, so that a defined rest position of the armature part which can be displaced in the axial direction is given when the actuator is not energized. The rest position is determined by the position of the press-fit ring.

In an advantageous embodiment, the press-in ring is pressed into a stainless steel sleeve part. At least one stainless steel sleeve part is used to separate the magnetic circuit from the gaseous medium or to encapsulate the component of the magnetic circuit in opposition to the delivery device for gaseous media proposed by the invention.

The delivery unit proposed according to the invention is used in such a way that the first gaseous medium, which is, for example, gaseous hydrogen, is the second gaseous medium, which is, for example, H ₂ recirculate from a fuel cell stack acts, promotes. For this purpose, the jet pump effect is utilized in the inventive proposed delivery unit by the first gaseous medium with higher flow velocity einschießt into the flow path of the second gaseous medium and consequently the second gaseous medium is further transported in the flow direction due to the higher flow rate of the first gaseous medium. The change in the flow velocity of the first gaseous medium takes place by changing the ratio of the flow cross sections for the recirculate A _Rezi to the flow cross section at the outlet opening of the annular gap A _{annular gap} . This ratio can be changed in a range of 8 to 50. The larger the ratio, the smaller the outlet opening of the annular gap and this in turn means that with very small annular gap openings, the flow velocity of the first gaseous medium leaving the annular gap is maximized.

Advantageously, in the inventive proposed delivery unit, the magnetic circuit or its components such as the designed as a solenoid actuator, the magnetic core against the gaseous media sealed by stainless steel sleeve parts and sealing rings.

In a further advantageous embodiment of the delivery unit proposed according to the invention, the housing part has a pipe extension, which is part of the mixing section and limits this with its inner circumferential surface.

In order to achieve an increase in the flow velocity of the first gaseous medium in the delivery unit proposed according to the invention, this flows within an annular gap which narrows in the direction of its discharge point in the central flow channel of the delivery unit proposed according to the invention. The annular gap is limited by a funnel-shaped configured guide element and the housing part, on which the tube extension is designed, which limits the mixing section.

The invention also relates to the use of the invention proposed delivery unit, in particular for the promotion of gaseous H ₂ -Rezirkulat, which by means of the present invention proposed delivery unit by utilizing the jet pump effect as recirculate from a fuel cell stack as needed, whether at full load, it was Partial load of the fuel cell system is dissipated.

Advantages of the invention

The advantages of the proposed solution according to the invention lie in the fact that now vertical shocks can be avoided, with which the first gaseous medium, which is used to promote the second gaseous medium by means of the jet pump effect, in the flow of the second gaseous medium, in particular the H. ₂ -Recirculates from the fuel cell stack, enters. Vertical impacts are particularly detrimental to an unhindered transport of the second gaseous medium, since the flow of the first gaseous medium occurring perpendicular to the flow direction of the second gaseous medium slows down the second gaseous medium, which counteracts unimpeded flow of the second gaseous medium out of the fuel cell stack. By the solution proposed according to the invention, vertical impacts, in particular of the first gaseous medium and the negative side effects associated therewith can be effectively prevented. In addition, the solution proposed according to the invention offers the advantage that the mixing section can be produced steplessly between a first mixing section length and a second mixing section length. For this purpose, the movable over the actuator armature part of the magnetic circuit is used in an advantageous manner, which is displaceable in the axial direction with appropriate energization of the particular designed as an electromagnet actuator.

The inner lateral surface of the anchor part, which concentrically encloses the tube extension on the housing part, serves advantageously as an extension of the substantially tubular design of the mixing section formed in the interior of the delivery unit.

The inventively proposed, the jet pump effect utilizing delivery unit provides its optimum in the full load range and is designed for this. In the full load range, the flow velocity is very high. However, occurring shocks prevent a sufficient volume flow, resulting in a deterioration of the mass flow. The proposed solution according to the invention can be prevented at full load shocks by the mixing section can be shortened in terms of its length. This results in an increase of the total volume flow by approx. 20%. The ratio of recirculate to propellant gas flow increases by 20%. Since the invention proposed, the jet pump effect ausnutzende delivery unit is designed for full load, can be achieved by the proposed solution according to the invention, an extension of the mixing section, especially at partial load operation. While at full load operation of the invention proposed delivery unit a short mixing section is desirable, it is exactly the opposite at part load, here a longer mixing section is desirable. These two requirements can be met by the inventively proposed design of the delivery unit, which does not have to deviate from a compact arrangement, ie a compact design.

list of figures

• 1 zeigt einen Längsschnitt durch das erfindungsgemäß vorgeschlagene Förderaggregat zur Förderung gasförmiger Medien

With reference to the drawing, the invention will be described below in more detail.

• 1 shows a longitudinal section through the invention proposed delivery unit for conveying gaseous media

In 1 is a delivery unit 10 shown, which is in particular designed as a jet pump. The delivery unit 10 includes a housing 11 and a housing part connected thereto 41 , Between the case 11 and the housing part 41 , for example, with each other by a screw connection 54 can be connected, is a magnetic circuit 18 added. The magnetic circuit 18 includes a magnetic core 20 , an enclosed by this magnetic coil 22 , which serves as an actuator, as well as an anchor part 12 , By at least a first stainless steel sleeve part 24 and a second stainless steel sleeve part 26 are the components of the magnetic circuit 18 against a first gaseous medium 30 , which is gaseous hydrogen, encapsulated.

In the illustration according to 1 is the invention proposed delivery unit 10 only half shown in longitudinal section. The delivery unit 10 is symmetrical to its axis of symmetry 36 educated.

1 moreover, shows that the anchor part 12 on a pipe extension 41.1 of the housing part 41 is picked up and by a spring 14 is charged. In the in 1 shown position of the anchor part 12 This is due to the effect of the biasing force of the spring 14 against a press-fit ring 16 hired in the first stainless steel sleeve part 24 is pressed. One side of the anchor part 12 lies a front page 56 of the magnetic circuit 18 opposite, next to the magnetic core 20 the serving as an actuator solenoid 22 receives. When the solenoid is energized 22 in the magnetic circuit 18 becomes the anchor part 12 against the action of the spring 14 attracted and moves relative to the stationary on the delivery unit 10 arranged housing part 41 , Concentric to the axis of symmetry 36 the inventive proposed delivery unit 10 , are the anchor part 12 and the housing part 41 arranged. On the housing part 41 Moreover, the pipe extension extends 41.1 , The pipe extension 41.1 forms with the movable armature part in the axial direction 12 a mixing section 40 , Inside the mixing section 40 become the first gaseous medium 30 and the second gaseous medium to be delivered 38 mixed together. In the first gaseous medium 30 it is gaseous H ₂ , which the mixing section 40 over an annular gap 32 and an inflow opening 48 flows in the delivery unit. The annular gap 32 narrows in the direction of its mouth in the central flow channel 34 , The annular gap 32 is from a guiding element 50 which serves as a funnel 52 can be executed, on the one hand formed; On the other hand, the annular gap 32 through the outside of the annular gap 32 assigning housing part 41 limited. That from the annular gap 32 exiting first gaseous medium 30 occurs essentially as a tangential flow in the central flow channel 34 due to its higher flow velocity, it breaks after entering the central flow channel 34 the second gaseous medium 38 , Which in particular is gaseous H ₂ -Rezirkulat a fuel cell stack with it. The gas mixture from the first gaseous medium 30 and the second gaseous medium 38 flows through the mixing section 40 , The mixing section 40 can be like in 1 indicated within an adjustment range 46 infinitely lengthened or shortened. The adjustment path within the adjustment range 46 is through a first mixing section length 42 and a second mixing section length 44 limited. The function of lengthening or shortening the mixing section 40 is due to the relative to the tube extension 41.1 on the housing part 41 mounted axially displaceable anchor part 12 accepted. This anchor part 12 is in 1 shown in the de-energized state. With the actuator switched off as a solenoid 22 becomes the anchor part 12 with its front side due to the action of the spring 14 to the press-fit ring 16 hired. In this in 1 illustrated case corresponds to the length of the mixing section 40 the length of the tube extension 41.1 of the housing part 41 extended by a partial length of the anchor part 12 to the first mixing section length 42 ,

Once the executed as a solenoid coil actuator 22 is energized, the anchor part 12 from the front side 56 of the magnetic circuit 18 attracted and - depending on the current supply of the solenoid coil 22 - The mixing distance is within the adjustment range 46 shortened. The way which the anchor part 12 with energization of the solenoid 22 towards the front 56 of the magnetic circuit 18 is by reference 44 denotes and corresponds to a second mixing section length 44 , Within the adjustment range 46 is depending on the current supply of the solenoid coil 22 a stepless change in length of the mixing section 40 possible. During the full load operation of the invention proposed pumping unit 10 a short length of mixing section 40 advantageous given by the second mixing section length 44 , as in 1 is shown in part-load operation of the invention proposed delivery unit an extension of the mixing section 40 Desirable, here represented by the first mixing section length 42 , as in 1 located.

By adjusting the length of the mixing section 40 By the solution proposed by the invention can be achieved in an advantageous manner that a deceleration of the flow of the second gaseous medium 38 in the central flow channel 34 is avoided. In particular, by the solution proposed by the invention, for example, a vertical shock can be prevented, via which the first gaseous medium 30 in the worst case from the annular gap 32 outlet and the flow of the second gaseous medium 38 concentric to the axis of symmetry 36 decelerating. If, however, an injection of the second gaseous medium 38 at the opening point of the annular gap 32 in the central flow channel 34 in the tangential direction, obstruct the flow of gaseous media 30 respectively. 38 not, but the effect of the Saugstrahleffektes is optimally for the promotion of the second gaseous medium 38 through the central flow channel 34 used.

The particular advantages of the proposed solution according to the invention are, above all, to be seen in the fact that when using a proportional magnet as a magnetic coil 22 in the magnetic circuit 18 the stepless adjustment of the mixing section lengths 42 . 44 within the adjustment range 46 can be realized; On the other hand, in the solution according to the invention there is the possibility of the length of the mixing section 40 by the Relativverfahrbarkeit of the anchor part 12 relative to the tube extension 41.1 , infinitely adjustable, so that in particular the requirements of the delivery unit 10 can be met in partial load operation.

When de-energized, the mixing section becomes 40 left unchanged long, which is very advantageous for the part load range. Here takes the mixing section 40 its maximum length, namely the first mixing section length 42 one. At full load, however, by energizing the solenoid coil 22 and thereby tightening the anchor part 12 the mixing section 40 to the second mixing section length 44 shortened, whereby the occurrence of a vertical impact and the associated throttling of the flow velocity of the second gaseous medium 38 through the central flow channel 34 counteracted. The anchor part 12 moves against the action of the spring 14 at the tube extension 41.1 back.

The invention is not limited to the embodiments described herein and the aspects highlighted therein. Rather, within the scope given by the claims a variety of modifications are possible, which are within the scope of expert action.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 7687171 B2 [0002]
• US 8999593 B2 [0003]

Claims (10)

Delivery unit (10), in which a first gaseous medium (30) promotes a second gaseous medium (38), with a housing (11) in which a magnetic circuit (18) with an actuator (22) is accommodated, characterized in that a mixing section (40), in which the gaseous media (30, 38) mix, is infinitely variable between a first mixing section length (42) and a second mixing section length (44). Delivery unit (10) according to Claim 1 , characterized in that the mixing section (40) by a housing part (41) and a relative to this movable armature part (12) is formed. Delivery unit (10) according to one of the preceding claims, characterized in that the armature part (12) via the designed as an electromagnet actuator (22) of the magnetic circuit (18) is adjustable in the axial direction. Delivery unit (10) according to one of the preceding claims, characterized in that the anchor part (12) by means of a spring (14) to an injection ring (16) is employed. Delivery unit (10) according to one of the preceding claims, characterized in that the press-fit ring (16) in a stainless steel sleeve part (24, 26) is pressed. Delivery unit (10) according to one of the preceding claims, characterized in that the first gaseous medium (30) is H ₂ and second gaseous medium (38) is H ₂ recirculation from a fuel cell stack. Delivery unit (10) according to one of the preceding claims, characterized in that the magnetic circuit (18) against the gaseous media (30, 38) through the stainless steel sleeve parts (24, 26) and sealing rings (28) is sealed. Delivery unit (10) according to one of the preceding claims, characterized in that on the housing part (41) a tube extension (41.1) is formed, which is part of the mixing section (40). Delivery unit (10) according to one of the preceding claims, characterized in that the first gaseous medium (30) flows to an annular gap (32) which is delimited by a guide element (50) and the housing part (41). Use of the delivery unit (10) according to one of Claims 1 to 9 for promoting H ₂ recirculation (38) in a fuel cell system.

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