To obtain adsorbent (10), meltable core which melts away during baking and binder are added to powdery activated carbon having microscopic pore whose size is less than 100 nm together with water and mixed together, then this mixture is molded into hollow cylindrical shape whose outside diameter is 4
To obtain adsorbent (10), meltable core which melts away during baking and binder are added to powdery activated carbon having microscopic pore whose size is less than 100 nm together with water and mixed together, then this mixture is molded into hollow cylindrical shape whose outside diameter is 4˜6 mm and baked. Although macroscopic pore whose side is 100 nm or more is formed by the meltable core, proportion of volume of the macroscopic pore to volume of the microscopic pore is adjusted to 65%˜150%. The adsorbent (10) has shape in cross section formed from cylindrical wall (10A) and cross-shaped radial wall (10B), and thickness of each part is within a range of 0.6˜3 mm. The adsorbent (10) of the present invention can satisfy adsorbing/desorbing performance of fuel vapor, flow resistance as a canister and strength of the adsorbent at the same time.
대표청구항▼
1. Adsorbent for a canister, the adsorbent forming macroscopic pore whose size is 100 nm or more by adding meltable core, which melts away during baking, to powdery activated carbon having microscopic pore whose size is less than 100 nm together with a binder and baking this mixture, the adsorbent c
1. Adsorbent for a canister, the adsorbent forming macroscopic pore whose size is 100 nm or more by adding meltable core, which melts away during baking, to powdery activated carbon having microscopic pore whose size is less than 100 nm together with a binder and baking this mixture, the adsorbent comprising: a hollow shape having, as an outside shape, a cylindrical shape whose outside diameter is 4 mm˜6 mm or a spherical shape whose diameter is 4 mm˜6 mm, also having a thickness of 0.6 mm˜3 mm at each part, anda proportion of a volume of the macroscopic pore to a volume of the microscopic pore in the adsorbent being set to 65%˜150%. 2. The adsorbent for the canister as claimed in claim 1, wherein: the adsorbent has a hollow shape in cross section, which is formed from a cylindrical wall at an outer side and a radial wall provided in a middle inside the cylindrical wall, anda thickness of each part of the cylindrical wall and the radial wall is within a range of 0.6 mm˜3 mm. 3. The adsorbent for the canister as claimed in claim 2, wherein: the thickness of each part of the cylindrical wall andthe radial wall is within a range of 0.7 mm˜0.8 mm. 4. The adsorbent for the canister as claimed in claim 2, wherein: the adsorbent has a cylindrical shape whose outside diameter is 4 mm˜6 mm and whose length is 2 mm˜12 mm. 5. The adsorbent for the canister as claimed in claim 2, wherein: the radial wall has a cross shape in cross section. 6. The adsorbent for the canister as claimed in claim 2, wherein: the radial wall extends radially in three directions from a center. 7. The adsorbent for the canister as claimed in claim 2, wherein: the radial wall has an I-shape in cross section which extends in two directions from a center. 8. The adsorbent for the canister as claimed in claim 1, wherein: in the canister that has a plurality of chambers in a flow direction, the adsorbent is used in a chamber that is nearest to an air release opening. 9. A canister whose case is filled with the adsorbent claimed in claim 1, comprising: inflow and outflow portions of fuel vapor that are provided at one end, in a flow direction, of the case; andan air release opening that is provided at the other end, in the flow direction, of the case, andan equivalent diameter of a flow passage which is filled with the adsorbent being an equivalent diameter more than seven times the outside diameter or the diameter of the adsorbent. 10. The canister as claimed in claim 9, wherein: the canister is provided with a plurality of chambers in the flow direction,at least a chamber that is nearest to the air release opening is filled with the adsorbent, andother chamber is filled with adsorbent that is formed from activated carbon having no macroscopic pore by the meltable core.
Hiltzik, Laurence H.; Jagiello, Jacek Z.; Tolles, Edward D.; Williams, Roger S., Method for reducing emissions from evaporative emissions control systems.
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