KR102315937B1 - Hydrogen Recirculation Apparatus and Method of Fuel Cell System for Vehicle - Google Patents

Abstract

The present invention is for improving the hydrogen utilization rate in a vehicle hydrogen fuel cell system. To a hydrogen recirculation apparatus and method for a vehicle hydrogen fuel system, the hydrogen recirculation apparatus for a vehicle hydrogen fuel system according to the present invention comprises: a hydrogen supply unit for supplying hydrogen; a fuel cell stack for generating fuel using supplied hydrogen; and a hydrogen recirculation blower that supplies hydrogen supplied from the hydrogen supply unit to the fuel cell stack and feeds back unreacted hydrogen that has passed through the fuel cell stack to the fuel cell stack.

Description

Hydrogen Recirculation Apparatus and Method of Fuel Cell System for Vehicle

The present invention relates to a hydrogen recirculation apparatus and method for a vehicle hydrogen fuel system, and more particularly, to a hydrogen recirculation apparatus and method for improving hydrogen utilization rate in a vehicle hydrogen fuel cell system.

In general, a hydrogen fuel system for a vehicle supplies more air and hydrogen to the fuel cell stack than the amount required for the cell reaction in order to secure performance and increase the lifespan of the fuel cell stack.

As described above, since 20 to 40% of the hydrogen supplied to the fuel cell stack is not used as fuel and is discharged from the fuel cell stack, the hydrogen fuel system for a vehicle has a problem in that fuel efficiency is low.

Many studies are being actively conducted to compensate for the disadvantage of low fuel efficiency of the hydrogen fuel system for vehicles.

That is, in recent years, many measures have been taken to increase the fuel efficiency of a hydrogen fuel system for a vehicle by recirculating hydrogen discharged from the fuel cell stack without being utilized as a fuel.

For example, as a hydrogen recirculation device, which is a key component of a hydrogen supply system for a fuel cell vehicle, a method of using an ejector is being sought.

The ejector has a simpler structure than the blower method, does not require lubricating oil because there is no rotating body, and is strong against noise and vibration. In addition, the ejector is easy to maintain, has a long service life, and has excellent cold start characteristics.

However, the ejector has a disadvantage in that it is difficult to be applied to a hydrogen supply system for a fuel cell vehicle with a wide operating range due to low de-design performance.

On the other hand, the blower has the advantage of being able to satisfy the off-design performance by changing the driving rotation speed.

Therefore, in order to compensate for the disadvantages of the ejector and the blower, research on a hydrogen recirculation device utilizing only the advantages of the ejector and the blower is being actively conducted.

For example, FIG. 1 is a view of a conventional hydrogen recirculation device to which an ejector and a blower are simultaneously applied. 1, the conventional hydrogen recirculation device includes an ejector 10 and a hydrogen recirculation blower 20, and utilizes only the advantages of the ejector 10 and the hydrogen recirculation blower 20 for hydrogen for fuel cell vehicles. It was intended to increase the fuel efficiency of the supply system.

The ejector 10 receives pure hydrogen from the hydrogen supply unit 40 . The ejector 10 supplies the pure hydrogen supplied from the hydrogen supply unit 40 to the fuel cell stack 30 .

The fuel cell stack 30 electro-chemically reacts the pure water channel supplied from the ejector 10 , and then transfers residual hydrogen to the hydrogen recirculation blower 20 through the hydrogen humidifier 50 .

The hydrogen recirculation blower 20 pumps the residual hydrogen transferred from the fuel cell stack 30 and delivers it to the ejector 10 .

The ejector 10 re-supply the residual hydrogen transferred from the hydrogen recirculation blower 20 to the fuel cell stack 30 again.

However, in this method, that is, even in a method utilizing only the advantages of the ejector 10 and the hydrogen recirculation blower 20, a lot of power is consumed to drive the hydrogen recirculation blower 20 in order to increase the hydrogen recirculation capacity, so the fuel cell stack There is a problem that a lot of power generated in (30) is consumed.

At the same time, this method may cause an overload on the motor and the hydrogen recirculation blower 20 for driving the hydrogen recirculation blower 20 to cause a problem in durability.

In addition, this method has a problem in that the hydrogen recirculation blower 20 is enlarged and takes up a lot of work space, thereby increasing the manufacturing cost.

The present invention is to solve the above problems, and to provide a hydrogen recirculation apparatus and method for a hydrogen fuel system for a vehicle capable of reducing power consumption of a hydrogen recirculation blower using hydrogen stored in a high-pressure hydrogen container. There is this.

In order to achieve the above object, a hydrogen recirculation apparatus of a vehicle hydrogen fuel system according to an aspect of the present invention includes a hydrogen supply unit for supplying hydrogen; a fuel cell stack for generating fuel using supplied hydrogen; and a hydrogen recirculation blower for supplying hydrogen supplied from the hydrogen supply unit to the fuel cell stack, and re-supplying unreacted hydrogen that has passed through the fuel cell stack to the fuel cell stack.

The hydrogen recirculation blower may include: a turbine driven using hydrogen supplied from the hydrogen supply unit and supplying the fuel cell stack; an impeller having one side connected to the turbine, driven according to the driving of the turbine, and supplying the unreacted hydrogen back to the fuel cell stack; and a motor using hydrogen supplied from the hydrogen supply unit and a driving force of the turbine during rotation.

When the rotation speed (driving force) of the turbine is smaller than a preset rotation speed, the motor rotates by receiving power from a separate power supply device as much as the insufficient driving force of the turbine.

The impeller is characterized in that the other side is connected to the motor to drive according to the driving of the motor together with the driving of the turbine.

The hydrogen recirculation blower generates power using the surplus rotation of the turbine when the turbine rotates using the supplied hydrogen supplied from the hydrogen supply unit, and when the rotational speed of the turbine is greater than a preset required rotational speed, a separate power supply is provided. It is characterized by charging.

A hydrogen recirculation method of a hydrogen recirculation apparatus including a hydrogen recirculation blower according to another aspect of the present invention comprises: supplying, by the hydrogen recycle blower, hydrogen supplied from the hydrogen supply unit to the fuel cell stack; and re-supplying unreacted hydrogen that has passed through the fuel cell stack to the fuel cell stack.

The re-supplying to the fuel cell stack may include: driving the turbine of the hydrogen recirculation blower to receive hydrogen from the hydrogen supply unit and supplying it to the fuel cell stack; supplying the unreacted hydrogen back to the fuel cell stack while driving the impeller of the hydrogen recirculation blower having one side connected to the turbine according to the driving of the turbine; and rotating the motor of the hydrogen recirculation blower using the hydrogen supplied from the hydrogen supply unit and the driving force of the turbine.

In the rotating using the driving force of the turbine, when the rotational speed (driving force) of the turbine is smaller than a preset rotational speed, the motor receives power from a separate power supply device as much as the insufficient driving force of the turbine and rotates It is characterized in that it includes.

The step of supplying the fuel cell stack back to the fuel cell stack may include driving the impeller connected to the motor on the other side according to the driving of the motor along with driving of the turbine.

The supplying of the supplied hydrogen to the fuel cell stack may include, when the turbine rotates using the supplied hydrogen supplied from the hydrogen supply unit, and when the rotational speed of the turbine is greater than a predetermined required rotational speed, surplus rotation of the turbine step to develop using; and charging the separate power supply using the generated power.

According to the present invention, it is possible to assist in driving the hydrogen recirculation blower using high-pressure hydrogen, thereby reducing power consumption of the hydrogen recirculation blower.

In addition, there is an advantage that can improve the recycling performance of hydrogen.

1 is a view of a conventional hydrogen recirculation device to which an ejector and a blower are applied at the same time.
2 is a view showing a hydrogen recirculation device of a vehicle hydrogen fuel system according to an embodiment of the present invention.
Figure 3 is a view showing the hydrogen recycle blower of Figure 2;
Figure 4 is a flow chart showing a hydrogen recycling method of the hydrogen recycling device according to an embodiment of the present invention.

Advantages and features of the present invention and methods of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be embodied in various different forms, only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention belongs It is provided so that those who have it can easily understand the scope of the invention, and the present invention is defined by the description of the claims. On the other hand, the terms used herein are for the purpose of describing the embodiments and are not intended to limit the present invention. In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase. As used herein, "comprises" or "comprising" refers to the presence or addition is not excluded.

Hereinafter, a hydrogen recirculation apparatus of a hydrogen fuel system for a vehicle according to an embodiment of the present invention will be described with reference to FIGS. 2 and 3 . 2 is a view showing a hydrogen recirculation apparatus of a hydrogen fuel system for a vehicle according to an embodiment of the present invention, and FIG. 3 is a view showing the hydrogen recirculation blower of FIG. 2 .

As shown in FIG. 2 , the hydrogen recirculation device 100 of the hydrogen fuel system for a vehicle according to an embodiment of the present invention includes a hydrogen supply unit 110 , a hydrogen recirculation blower 120 , an ejector 130 and a fuel cell stack ( 140).

When the supply valve is adjusted according to the set required output, the hydrogen supply 110 supplies hydrogen to the hydrogen recirculation blower 120 according to the adjusted supply valve.

For example, when the required output is set as the first requested output and the supply valve is adjusted to the first position according to the set first requested output, the hydrogen supply unit 110 supplies high-pressure hydrogen according to the supply valve adjusted to the first position. Hydrogen is supplied to the recirculation blower (120).

In addition, when the required output is set to the second requested output and the supply valve is adjusted to the second position according to the set second requested output, the hydrogen supply unit 110 supplies low-pressure hydrogen according to the supply valve adjusted to the second position. Hydrogen is supplied to the recirculation blower (120).

Since the present invention is to reduce the power consumption of the hydrogen recycle blower 120 by using high-pressure hydrogen, the hydrogen recycle blower 120 can use high-pressure hydrogen in the following according to the purpose of the present invention.

The request output set here will be described as an example of the first request output.

The hydrogen recirculation blower 120 includes a turbine 111 , an impeller 112 and a motor 113 as shown in FIG. 3 .

The turbine 111 is driven using hydrogen supplied from the hydrogen supply unit 110 (hereinafter, referred to as “supply hydrogen”).

For example, when the supply hydrogen is supplied through the supply hydrogen inlet, the turbine 111 rotates using the supplied hydrogen supply. In addition, the turbine 111 transfers the supply hydrogen to the ejector 130 through the supply hydrogen outlet while rotating.

The ejector 130 supplies supply hydrogen pumped from the turbine 111 through the supply hydrogen outlet to the fuel cell stack 140 .

One side of the impeller 112 is connected to the turbine 111 , and the other side is connected to the motor 113 . The impeller 112 is driven according to the rotation of the turbine 111 , and also driven according to the rotation of the motor 113 .

As described above, the impeller 112 is driven according to the rotation of the turbine 111 and the motor 113 , and hydrogen transferred from the fuel cell stack 140 through the recirculation inlet (hereinafter referred to as “recycled hydrogen”). compress the The impeller 112 pumps the compressed recycle hydrogen and delivers it to the ejector 130 through the recirculation outlet.

The ejector 130 supplies the recirculated hydrogen pumped from the impeller 112 through the recirculation outlet back to the fuel cell stack 140 .

The motor 113 uses high-pressure hydrogen supplied from the hydrogen supply unit 110 and driving force of the turbine 111 during rotation.

In addition, when the rotation speed (driving force) of the turbine 111 is smaller than a preset required rotation speed, the motor 113 rotates by using the electricity of the vehicle battery by the insufficient amount of the driving force of the turbine 111 .

As described above, in the hydrogen recirculation apparatus 100 of a vehicle hydrogen fuel system according to an embodiment of the present invention, the hydrogen recirculation blower 120 uses high-pressure hydrogen supplied from the hydrogen supply unit 110 to the turbine 111 . is driven, and the driven turbine 111 pumps the supplied hydrogen and supplies it to the fuel cell stack 140 through the ejector 130 .

In addition, the hydrogen recirculation blower 120 drives the impeller 112 according to the rotation of the turbine 111 and the motor 113 , and the driven impeller 112 pumps the recirculated hydrogen supplied from the fuel cell stack 140 . This is to re-supply the fuel cell stack 140 through the ejector 130 .

As such, the hydrogen recirculation apparatus 100 of the hydrogen fuel system for a vehicle according to an embodiment of the present invention operates the hydrogen recirculation blower 120 using the supplied hydrogen supplied from the labor supply unit 110 to supply hydrogen and recycle hydrogen. Since it can be supplied to the fuel cell stack 140 , the hydrogen efficiency of the vehicle hydrogen fuel system can be increased while using the output of the fuel cell stack 140 to a minimum.

On the other hand, when the hydrogen recirculation blower 120 rotates the turbine 111 using the high-pressure supplied hydrogen supplied from the hydrogen supply unit 110 , when the rotation speed of the turbine 111 is greater than the predetermined required rotation speed, a separate power source Without receiving a supply, that is, without using the power of the vehicle battery, it is possible to charge the vehicle battery by generating electricity using the surplus rotation of the turbine 111 .

Hereinafter, a hydrogen recycling method of a hydrogen recycling device according to an embodiment of the present invention will be described with reference to FIG. 4 . 4 is a flowchart illustrating a hydrogen recycling method of the hydrogen recycling device 100 according to an embodiment of the present invention.

As shown in FIG. 4 , the hydrogen recirculation device 100 allows the hydrogen supply unit 110 to supply hydrogen to the hydrogen recycle blower 120 ( S400 ).

The hydrogen recirculation apparatus 100 checks whether the requested output of the fuel cell stack 140 is the first requested output or the second requested output (S401). As a result of checking, if the requested output of the fuel cell stack 140 is the first requested output, the hydrogen supply valve of the hydrogen supply unit 110 is adjusted to the first position (S402).

As described above, as the hydrogen supply valve is adjusted to the first position, the hydrogen supply unit 110 supplies the supply hydrogen of the first hydrogen flow rate to the hydrogen recirculation blower 120 ( S403 ).

The turbine 111 of the hydrogen recirculation blower 120 rotates with the first turbine driving force using the supplied hydrogen of the first hydrogen flow rate supplied from the hydrogen supply unit 110 (S404).

The hydrogen recirculation apparatus 100 checks whether the rotation speed of the turbine 111 does not exceed a predetermined hydrogen blower required rpm (rotation speed) (S405).

As a result of checking, when the rotational speed of the turbine 111 exceeds the preset required rotational speed of the hydrogen blower, the hydrogen recirculation apparatus 100 generates power using the excess rotational speed, that is, the surplus driving force (S406). The hydrogen recirculation device 100 charges a vehicle battery using electricity generated by power generation (S407).

However, as a result of the check, when the rotation speed (driving force) of the turbine 111 does not exceed the preset number of rotations required for the hydrogen blower, the hydrogen recirculation device 100 is the hydrogen recirculation blower 120 by the insufficient driving force of the turbine 111 . of the motor 113 is driven by the driving force of the first hydrogen blower motor (S408).

Then, the hydrogen recirculation device 100 recycles the hydrogen transferred from the fuel cell stack 140 ( S413 ).

For example, the impeller 112 of the hydrogen recirculation blower 120 drives according to the rotation of the turbine 111 and the motor 113 , and hydrogen transferred from the fuel cell stack 140 through the recirculation inlet (hereinafter referred to as “recycle hydrogen”). ") is compressed. The impeller 112 pumps the compressed recycle hydrogen and delivers it to the ejector 130 through the recirculation outlet. The ejector 130 supplies the recirculated hydrogen pumped from the impeller 112 through the recirculation outlet back to the fuel cell stack 140 .

As a result of checking in step S401 , if the requested output of the fuel cell stack 140 is the second requested output, the hydrogen recirculation apparatus 100 adjusts the hydrogen supply valve of the hydrogen supply unit 110 to the second position ( S409 ).

As described above, as the hydrogen supply valve is adjusted to the second position, the hydrogen supply unit 110 supplies the supply hydrogen of the second hydrogen flow rate to the hydrogen recirculation blower 120 (S410).

The turbine 111 of the hydrogen recirculation blower 120 rotates with the second turbine driving force using the supplied hydrogen of the second hydrogen flow rate supplied from the hydrogen supply unit 110 (S411).

The hydrogen recirculation device 100 drives the motor 113 of the hydrogen recirculation blower 120 with the second hydrogen blower motor driving force (S412).

Then, the hydrogen recirculation device 100 recycles the hydrogen transferred from the fuel cell stack 140 ( S413 ).

Although the configuration of the present invention has been specifically described with reference to the preferred embodiment and the accompanying drawings, this is merely an example and various modifications are possible within the scope without departing from the technical spirit of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments and should be defined by the claims described below as well as the claims and equivalents.

100: hydrogen recirculation device 110: hydrogen supply unit
120: hydrogen recirculation blower 130: ejector
140: fuel display stack

Claims (10)

In the hydrogen recirculation device of a vehicle hydrogen fuel system,
a hydrogen supply unit for supplying hydrogen;
a fuel cell stack for generating fuel using supplied hydrogen; and
and a hydrogen recirculation blower that supplies hydrogen supplied from the hydrogen supply unit to the fuel cell stack and feeds back unreacted hydrogen that has passed through the fuel cell stack to the fuel cell stack,
The hydrogen recirculation blower includes a turbine, an impeller and a motor, wherein the motor receives power from a separate power supply device as much as the insufficient driving force of the turbine when the rotation speed (driving force) of the turbine is smaller than a preset rotation speed and rotates thing
Hydrogen recirculation device of hydrogen fuel system for in-vehicle vehicles. According to claim 1,
The turbine is driven using the hydrogen supplied from the hydrogen supply unit and supplied to the fuel cell stack, and one side of the impeller is connected to the turbine and driven according to the operation of the turbine, and the unreacted hydrogen is supplied to the fuel cell feedback to the stack, and the motor uses the hydrogen supplied from the hydrogen supply unit and the driving force of the turbine when rotating
Hydrogen recirculation device of hydrogen fuel system for in-vehicle vehicles. delete 3. The method of claim 2,
The other side of the impeller is connected to the motor to drive according to the driving of the motor along with the driving of the turbine
Hydrogen recirculation device of hydrogen fuel system for in-vehicle vehicles. According to claim 1,
The hydrogen recirculation blower generates power using the surplus rotation of the turbine and charges a separate power supply when the turbine rotation speed is greater than a preset required rotation speed when the turbine rotates using the hydrogen supplied from the hydrogen supply unit. to make
Hydrogen recirculation device of hydrogen fuel system for in-vehicle vehicles. In the hydrogen recirculation method of a hydrogen recirculation device comprising a hydrogen supply unit, a fuel cell stack and a hydrogen recirculation blower,
(a) supplying, by the hydrogen recirculation blower, hydrogen supplied from the hydrogen supply unit to the fuel cell stack; and
(b) feeding back unreacted hydrogen that has passed through the fuel cell stack to the fuel cell stack,
In the step (b), the motor included in the hydrogen recirculation blower is rotated using the hydrogen supplied from the hydrogen supply unit and the driving force of the turbine included in the hydrogen recirculation blower, the number of revolutions (driving force) of the turbine is When it is less than the set rotation speed, to rotate the motor by receiving power from a separate power supply device as much as the insufficient driving force of the turbine
A method of hydrogen recirculation in a phosphorus recirculation device. The method of claim 6, wherein (b) step,
(b-1) driving the turbine by receiving hydrogen supplied from the hydrogen supply unit and supplying it to the fuel cell stack; and
(b-2) the impeller of the hydrogen recirculation blower connected to the turbine on one side is driven according to the driving of the turbine and comprising the step of feeding back the unreacted hydrogen to the fuel cell stack
A method of hydrogen recycling in a phosphorus hydrogen recycling device. delete The method of claim 7, wherein the step (b-2) comprises:
The other side is the step of driving the impeller connected to the motor according to the driving of the motor along with the driving of the turbine
A method of hydrogen recycling in a phosphorus hydrogen recycling device. The method of claim 6, wherein (a) step,
When the turbine rotates using the hydrogen supplied from the hydrogen supply unit, when the rotation speed of the turbine is greater than a predetermined required rotation speed, generating power using the surplus rotation of the turbine; and
Comprising the step of charging the separate power supply using the generated power
A method of hydrogen recycling in a phosphorus hydrogen recycling device.

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