JP3027057B2 - In-vehicle hydrogen supply device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an in-vehicle hydrogen supply device for supplying hydrogen upstream of an exhaust gas purifying catalyst.

[0002]

2. Description of the Related Art Conventionally, this kind of on-vehicle hydrogen supply apparatus includes a catalyst for burning unburned components upstream of a catalyst for purifying exhaust gas in an exhaust pipe and heating the catalyst when the engine is started. It was known to supply hydrogen upstream.
This is a hydrogen generator with a built-in cell that generates hydrogen gas and water by water electrolysis, a water tank that supplies water to the hydrogen generator, and water sealing water that is supplied from the water tank to seal the hydrogen gas. And a hydrogen tank that stores hydrogen gas generated by the hydrogen generator at a pressure higher than the pressure in the exhaust pipe, and incorporates the pressure hydrogen gas stored in the hydrogen tank with water sealing water, and converts the water sealing water to hydrogen. It has a steam-water separator that returns to the tank and discharges the pressure hydrogen gas to the exhaust pipe.The hydrogen gas is pumped upstream of the catalyst immediately after the start of the engine to ignite the hydrogen gas and unburned components. The aim was to improve the ability to purify the exhaust gas when starting the engine by burning the catalyst and quickly warming up the catalyst.

[0003]

However, in the above-described hydrogen supply apparatus for a vehicle, since the water seal water supplied from the water tank is stored in the hydrogen tank, the engine is started in winter or the like. In such a case, the water sealing water in the hydrogen tank freezes, and the pressure hydrogen gas stored in the hydrogen tank is confined in the hydrogen tank and is not supplied to the exhaust pipe via the steam separator.

An object of the present invention is to supply the pressure hydrogen gas in the hydrogen tank to the exhaust pipe reliably and promptly immediately after starting the engine in winter or the like.

[0005]

Configuration of the Invention

[0006]

The technical measures taken in the present invention to solve the above technical problem are to burn unburned components upstream of a catalyst for purifying exhaust gas in an exhaust pipe at the time of engine start. And a hydrogen supply device for heating the catalyst, which is equipped with a cell that generates hydrogen gas by water electrolysis, a water tank that supplies water to the hydrogen generator, and a hydrogen generator. Separated hydrogen gas and water flowing together with the hydrogen gas from the hydrogen generator, a water-water separator for returning a water component to the water tank, and storing the antifreeze, and separated by the water-water separator. A hydrogen tank that stores the hydrogen gas component at a pressure higher than the pressure in the exhaust pipe, the pressure hydrogen gas stored in the hydrogen tank is taken in together with the antifreeze, the antifreeze component is returned to the hydrogen tank, and the pressure hydrogen gas component is exhausted. It is that having a gas-liquid separator to release.

[0007]

According to the above technical means, when the engine is started in winter, that is, when the temperature is low, the antifreeze in the hydrogen tank does not freeze, so that the pressure hydrogen gas is quickly and reliably stored in the hydrogen tank without being confined in the hydrogen tank. It is discharged to the exhaust pipe through the separator.

Further, since water generated by the hydrogen generator and hydrogen gas are separated by the steam separator before the hydrogen gas is supplied to the hydrogen tank, no water is supplied to the hydrogen tank. That is, there is no possibility that water and antifreeze mix in the hydrogen tank.

[0009]

An embodiment of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of a hydrogen supply device according to the present embodiment, and FIG. 2 is a schematic diagram of an exhaust gas purification device to which the hydrogen supply device according to the present embodiment is applied.

As shown in FIG. 1, a hydrogen supply device 1
Is provided with a water tank 2 containing a pump 2a which is always kept warm. This water tank 2 is provided with a pipe 30 and a pipe 31.
Is connected to the hydrogen generator 4. The pipe 30
This is for supplying water from the water tank 2 to the hydrogen generator 4 via the pump 2a.
A filter 3 is provided. This filter 3
It purifies water supplied from the water tank 2 via the pump 2a. A cell 4a is built in the hydrogen generator 4, and is subjected to electrolysis using stored water.
Oxygen gas is generated on the anode side, and hydrogen gas is generated on the cathode side. In the hydrogen generator 4,
A limit switch 9 is attached, and a solenoid valve 8 is provided in the middle of the pipe 31. The level of the water stored in the hydrogen generator 4 is detected by the limit switch 9, and the solenoid valve 8 is controlled by the controller 40 based on the detection signal.
By operating a, the water in the water tank 2 is supplied to the hydrogen generator 4 via the pipe 30, and is returned to the water tank 2 via the pipe 31 if the water level is equal to or higher than a predetermined water level.

A steam-water separator 5 is connected to the cathode side of the hydrogen generator 4 via a pipe 32, and hydrogen gas generated on the cathode side and water accompanying the hydrogen gas are connected through the pipe 32. It is supplied to the steam separator 5. The steam separator 5 is connected to the water tank 2 via a pipe 33 and connected to the hydrogen tank 6 via a pipe 34.

The steam-water separator 5 separates hydrogen gas generated on the cathode side from water entrained with the hydrogen gas, and separates the water component into the pipe 33 and the solenoid valve 1 disposed in the middle of the pipe 33.
Reflux to the water tank via 0. The solenoid valve 10 is controlled by a controller 40. In the middle of the pipe 34, the pipe has 35 branches, as shown in FIG. 2, the pipe 35 is NO _X in the exhaust pipe 50
It communicates with a nozzle 56 located upstream of the catalyst 52. Therefore, the hydrogen gas component separated by the steam separator 5 is diverted in the middle of the pipe 34 while the bypass pipe 3
5, and is supplied to the hydrogen tank 6 on the other hand. In the middle of the bypass pipe 35, the solenoid valve 11,
A pressure switch 12 and a check valve 13 are sequentially provided. The pressure switch 12 detects the pressure of the hydrogen gas supplied to the pipe 35, and the controller 40 controls the solenoid valve 11 based on the detection signal, and opens the solenoid valve 11 as necessary. It has become. The check valve 13 is for preventing exhaust gas in the exhaust pipe 50 from flowing back to the bypass pipe 35, and opens when a predetermined pressure (generally, 1.5 kg / cm ² ) is applied. It is designed to give a valve.

A check valve 14 and a pressure switch 15 are arranged on the hydrogen tank 6 side from the junction of the pipe 34 and the bypass pipe 35. The pressure switch 15 is for detecting the pressure of the hydrogen gas supplied into the hydrogen tank 6.
Is higher than the pressure in the exhaust pipe 50 (generally,
3.0 kg / cm ² ) of hydrogen gas is stored. Further, an antifreeze such as ethylene glycol is stored in the hydrogen tank 6 so that it does not freeze even in winter. Check valve 1
4 prevents the antifreeze in the hydrogen tank 6 from flowing back to the water / water separator 5 to mix the antifreeze with the water in the water / water separator 5 and to prevent the antifreeze from flowing back to the bypass pipe 35. It is for.

The hydrogen tank 6 is connected to the gas-liquid separator 7 via pipes 36 and 37. The pressure hydrogen gas in the hydrogen tank 6 is supplied to the gas-liquid separator 7 together with the antifreeze via the pipe 36 and the electromagnetic valve 16 arranged in the middle of the pipe 36. The gas-liquid separator 7 separates the pressure hydrogen gas and the antifreeze, and returns the antifreeze into the hydrogen tank 6 via the pipe 37 and the electromagnetic valve 17 provided in the middle of the pipe 37.
Further, the pressure hydrogen gas is supplied to the nozzle 55 located on the upstream side of the three-way catalyst 51 in the exhaust pipe 50 via the pipe 38. A check valve 18 and an orifice 19 which are opened when a predetermined pressure (generally, 0.5 kg / cm ² ) is applied are provided in the middle of the pipe 38. The check valve 18 is used to supply the exhaust gas
Backflow from 0 to the pipe 38 is prevented.

As shown in FIG. 2, an air pump 50 is connected via a port 54 to an upstream side of a three-way catalyst 51 in an exhaust pipe 50 of an exhaust gas purification apparatus to which the present embodiment is applied. Secondary air is introduced. On the three-way catalyst 51 side, a nozzle 55 to which a pressure hydrogen gas is supplied from the hydrogen tank 6 of the hydrogen supply device 1 is provided with an exhaust pipe 5.
It is arranged so as to communicate with zero. On the three-way catalyst 51 side of the nozzle 55, ignition is performed by a high-pressure coil 45 controlled by the controller 40.
Unburned components such as C and CO are burned together with hydrogen gas and secondary air. By forcibly heating the three-way catalyst 51 by this combustion energy, the three-way catalyst 51 is quickly activated, and HC, CO, etc. are purified by the three-way catalyst 51. On the other hand, of the NO _x catalyst on the upstream side, are a nozzle 56 is arranged that hydrogen gas is supplied from the hydrogen generator 4 of the aforementioned hydrogen supply device 1, and the hydrogen gas and the NO _x is of the NO _x catalyst NO _x is purified by causing a reduction reaction by the action.

The operation of the hydrogen supply device according to this embodiment will be described.

When an ignition switch (not shown) is turned on at the time of starting the engine, the solenoid valve 16 in the pipe 36 is opened by the controller 40, and the pressure hydrogen gas previously stored in the hydrogen tank 6 is released together with the antifreeze. Piping 36
Is supplied to the gas-liquid separator 7. The pressure hydrogen gas and the antifreeze are separated in the gas-liquid separator 7, and the pressure hydrogen gas component is discharged to the nozzle 55 through the pipe 38 while resisting the pressure specified by the check valve 18. In this way, the pressure hydrogen gas is quickly supplied into the exhaust pipe 50.

At the same time as the pressure hydrogen gas from the hydrogen tank 6 is supplied to the upstream side of the three-way catalyst 51, the air pump 53
And the high-pressure coil 45 is operated, and the pressure hydrogen gas and the secondary air are burned together with unburned components such as HC and CO. The three-way catalyst 51 can be forcibly heated by the combustion energy, and the three-way catalyst 51 quickly becomes active.
Purifies unburned components such as CO.

After a lapse of a predetermined time, the solenoid valve 17 in the pipe 37 is opened by the controller 40, and the antifreeze supplied to the gas-liquid separator 7 together with the pressure hydrogen gas is returned to the hydrogen tank 6 through the pipe 37. Thereafter, the solenoid valve 16 is closed by the controller 40.

On the other hand, at the same time as the above operation, the water in the water tank 2 is supplied to the hydrogen generator 4 until the pump 2a kept warm in the water tank 2 is operated and the limit switch 9 is turned on. Here, since the pump 2a is always kept warm, even if the water stored in the water tank 2 is frozen in winter, the water in the pump 2a and the water around the pump 2a are supplied to the hydrogen generator 4 immediately. Is done.

After the solenoid valve 16 in the pipe 36 is opened,
The hydrogen generator 4 is activated, and in the cell 4a in the hydrogen generator 4,
Water electrolysis occurs, and oxygen gas is generated on the anode side, and hydrogen gas is generated on the cathode side. Oxygen gas generated on the anode side is introduced into the intake system of the engine,
Or is supplied to the upstream side of the three-way catalyst 51 and the NO _x catalyst 52 in 0, it is released into the atmosphere. The hydrogen gas generated on the cathode side is supplied to a steam-water separator 5 via a pipe 32 together with the water in the hydrogen generator 4, and the steam-water separator 5 separates the hydrogen gas and water. Solenoid valve 1 as appropriate by controller 40
0 is opened, and the separated water component is returned to the water tank 2 via the pipe 33.

The pressure of the hydrogen gas supplied to the pipe 35 is equal to the pressure of the check valve 13 (generally, 1.5 kg / c
m ² ), the pressure switch 12 is always set to O
The state is N, and the solenoid valve 11 is opened by the controller 40 based on the signal. On the other hand, piping 3
The pressure switch 15 disposed in the switch 4 is also in the ON state. Accordingly, the hydrogen gas component generated by the hydrogen generator 4 and separated by the steam separator 5 is supplied to the pipe 35 through a part of the pipe 34, and is also supplied to the hydrogen gas through the pipe 34 and the check valve 14. It is stored in the tank 6. When the pressure of the hydrogen gas supplied to the pipe 35 reaches the pressure of the check valve 13 (generally, 1.5 kg / cm ² ), the pressure switch 12 is switched from ON to OFF, and the controller is controlled based on the signal. The solenoid valve 11 is closed by 40. In this state, all the hydrogen gas components generated by the hydrogen generator 4 are stored in the hydrogen tank 6 via the pipe 34 and the check valve 14 (about 2.0 kg).
/ Cm ² ).

During high-speed operation, the solenoid valve 11 is appropriately opened by the controller 40, and as described above, hydrogen gas reaching the pressure of the check valve 13 is discharged to the nozzle 56 through the pipe 35, and this hydrogen gas is discharged. causing a reduction reaction with NO _x by the action of the NO _x catalyst 52 for purifying NO _x.
Further, the solenoid valve 11 is closed according to the running condition, and the solenoid valve 1 is closed.
While the valve 1 is closed, the hydrogen gas generated by the hydrogen generator 4 is stored in the hydrogen tank 6. This hydrogen tank 6
When the pressure of the hydrogen gas stored in the inside reaches a predetermined pressure (generally, 3.0 kg / cm ² ), the pressure switch 1
5 is switched from ON to OFF, and the supply of hydrogen gas to the hydrogen tank 6 is ended by the controller 40 based on the signal.

When the operation of the hydrogen generator 4 is completed, the solenoid valve 8 is opened for a predetermined time by the controller 40, and all the water stored in the hydrogen generator 4 is returned to the water tank 2 via the pipe 31.

As described above, in the present embodiment, when the engine is started in winter, that is, when the temperature is low, the antifreeze in the hydrogen tank 6 does not freeze, so the pressure hydrogen gas in the hydrogen tank 6 is confined in the hydrogen tank 6. The exhaust gas is quickly and reliably discharged to the upstream side of the three-way catalyst 51 in the exhaust pipe 50 via the gas-liquid separator 7. There is no danger of the pipe 36 from the hydrogen tank 6 to the gas-liquid separator 7 and the pipe 37 from the gas-liquid separator 7 to the hydrogen tank 6 exploding.

Since the hydrogen gas generated by the hydrogen generator 4 before the hydrogen gas is supplied to the hydrogen tank 6 and the water accompanying the hydrogen gas are separated by the steam separator 5, the hydrogen tank 6 Is not supplied with water. That is, there is no fear that water and antifreeze mix in the hydrogen tank 6.

Further, since water is not stored in the hydrogen generator 4 immediately after the engine is started, the hydrogen generator 4
There is no freezing inside, and the hydrogen generator 4 can operate reliably.

[0029]

The present invention has the following effects.

When the engine is started in winter, that is, at a low temperature, the antifreeze in the hydrogen tank does not freeze. Therefore, the pressure hydrogen gas is quickly and reliably inserted into the exhaust pipe through the gas-liquid separator without being confined in the hydrogen tank. Released.

[Brief description of the drawings]

FIG. 1 is a schematic diagram of a hydrogen supply device according to the present embodiment.

FIG. 2 is a schematic diagram of an exhaust gas purification device to which the present embodiment is applied.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Hydrogen supply apparatus 2 Water tank 4 Hydrogen generator 5 Gas-water separator 6 Hydrogen tank 7 Gas-liquid separator 50 Exhaust pipe

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-63-68714 (JP, A) JP-A-4-99189 (JP, A) JP-A-1-247591 (JP, A) JP-A 48-48 1618 (JP, A) JP-A-4-318214 (JP, A) Patent 2910958 (JP, B2) (58) Fields investigated (Int. Cl. ⁷ , DB name) F01N 3/00-3/38

Claims (1)

(57) [Claims] 1. An in-vehicle hydrogen supply device for burning unburned components upstream of a catalyst for purifying exhaust gas in an exhaust pipe and heating the catalyst when the engine is started, wherein the hydrogen gas is supplied by water electrolysis. A hydrogen generator having a built-in cell, a water tank for supplying water to the hydrogen generator, and a hydrogen gas generated by the hydrogen generator and water flowing from the hydrogen generator together with the hydrogen gas. Separate,
A water / water separator for returning a water component to the water tank, and a hydrogen tank for storing antifreeze and storing the hydrogen gas component separated by the gas / water separator at a pressure higher than the pressure in the exhaust pipe. A gas-liquid separator that takes in the pressure hydrogen gas stored in the hydrogen tank together with the antifreeze, recirculates the antifreeze component to the hydrogen tank, and discharges the pressure hydrogen gas component to the exhaust pipe. For hydrogen supply.