JP3948248B2 - Adsorption rotor and adsorption apparatus using the same - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an adsorption rotor, and more particularly to an adsorption rotor used in an adsorption device including a dehumidifying device and a deodorizing device. The present invention also relates to a suction device using such a suction rotor.
[0002]
[Prior art]
Adsorption devices such as a dehumidifying device and a deodorizing device generally include a honeycomb rotor having a honeycomb structure formed by specially molding fine-particle activated carbon, silica gel, or zeolite. This kind of adsorption device further includes a casing in which the rotor is rotatably arranged. Inside the casing, an adsorption zone formed on both axial sides of a predetermined area of the rotor by a partition wall, and other areas It is divided into playback zones formed on both sides in the axial direction.
[0003]
In such a device, the rotor is continuously driven to be dehumidified, deodorized and regenerated by continuously changing the area that is rotated and driven by a motor or the like and the area that is regenerated.
[0004]
For example, in a dehumidifier, air containing sufficient moisture is first guided to an adsorption zone and passes through a rotating honeycomb rotor. At this time, moisture in the air is adsorbed by the rotor and removed from the air, and dry air blows out from the rotor. Thereby, dry air is supplied indoors. And the area | region which adsorb | sucked the water | moisture content of the rotor rotates, it moves to a reproduction | regeneration zone, and the air for a reproduction | regeneration (warm air) is sent from a reverse direction to an adsorption | suction zone. As a result, moisture is expelled from the region where the rotor has adsorbed moisture, and the rotor is regenerated.
[0005]
Similarly, in the deodorization device, in the adsorption zone, low concentration organic gas, bad odor, etc. in the air are adsorbed by the rotor to remove these substances from the air, and in the regeneration zone, outside air is sent in the opposite direction. Organic gas or the like is removed from the rotor.
[0006]
The suction rotor used in such a suction device usually includes a basic frame having a plurality of radially extending fins and a plurality of suction blocks arranged circumferentially on the basic frame. Each of the plurality of suction blocks is arranged between two adjacent fins and held by the fins.
[0007]
[Problems to be solved by the invention]
In the conventional adsorption device, high-temperature air is sent in the regeneration zone. At this time, since the non-combustible or flame-retardant material is used, the adsorption block does not burn, but thermally expands when high-temperature air is blown. Then, it may receive a pressing force due to a reaction from the fin holding the block, and may cause a crack. Such block expansion occurs not only when high-temperature air is blown in the regeneration zone, but also when a large amount of moisture is adsorbed in the adsorption zone.
[0008]
Therefore, in view of such problems, the suction block disposed between two adjacent fins is disposed on the inner peripheral block disposed on the inner peripheral side and on the outer peripheral side of the inner peripheral block. A suction rotor divided into outer peripheral blocks has already been proposed.
[0009]
According to such a suction rotor, in a conventional size (less than 2 m in diameter), the degree of expansion of each block can be reduced as compared with the conventional suction rotor, and the degree of expansion is somewhat increased. Also, the expansion to the extent that cracks can occur can be suppressed.
[0010]
However, in the case of a large rotor (diameter 2 m or more), the circumferential length of the outer peripheral block is significantly larger than that of the inner peripheral block, which increases the degree of expansion of the outer peripheral block and effectively prevents the generation of cracks. There was a problem that it could not be suppressed.
[0011]
An object of the present invention is to suppress the occurrence of cracks in a suction rotor having a plurality of suction blocks by reducing the degree of expansion of the suction blocks.
[0012]
[Means for Solving the Problems]
The adsorption rotor according to claim 1 has a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device, and includes a basic frame and a plurality of hexahedral inner and outer adsorption blocks. ing. The basic frame has a plurality of fins extending radially. The plurality of inner peripheral suction blocks are arranged circumferentially on the inner peripheral side of the basic frame. The plurality of outer peripheral suction blocks are disposed on the outer peripheral side of the inner peripheral suction block. Between the two adjacent fins, n (n ≧ 1) inner circumferential suction blocks and m (m ≧ n) outer circumferential suction blocks are arranged.
[0013]
In this suction rotor, an inner peripheral block and outer peripheral blocks larger in number than the inner peripheral blocks are arranged between two adjacent fins. According to such a configuration, it is possible to reduce the size of the blocks arranged on the outer peripheral side, thereby suppressing the degree of expansion of each block and suppressing the occurrence of cracks.
[0014]
Further, the adsorption rotor according to claim 1 further comprising a unit frame for accommodating the m-number of the outer peripheral side suction block as a unit.
[0015]
When the number of outer peripheral blocks increases, handling performance during transportation is lacking, and the assembly work of the suction rotor becomes complicated.
[0016]
Therefore, in this suction rotor, such an outer peripheral block is housed as a unit in the unit frame, thereby improving handling at the time of transportation and facilitating the work at the time of assembly.
[0017]
A suction rotor according to a second aspect is the suction rotor according to the first aspect, wherein a positioning portion for positioning in the axial direction of the rotor is formed on a surface of the unit frame that faces the outer peripheral suction block. The m outer peripheral suction blocks are formed with engaging portions that engage with the positioning portions of the unit frame.
[0018]
When the suction rotor is attached to the suction device, it is usually necessary to seal between the suction zone and the regeneration zone. For this reason, the surfaces on both sides in the axial direction are in contact with seal members extending from the partition wall. It will be in the state.
[0019]
However, if the outer peripheral side blocks are divided and the number thereof is increased, the axial side surface of the rotor formed by these blocks may not be flush. In such a case, there is a possibility that a stable sealing effect by the sealing member cannot be obtained.
[0020]
Therefore, in this suction rotor, the axial position of each block is positioned with respect to the unit frame, so that both surfaces of the suction rotor in the axial direction are kept in the surface position, and stable sealing by the seal member when attached to the suction device The effect is obtained.
[0021]
An adsorption rotor according to a third aspect of the present invention has a diameter of 2 m or more used for an adsorption device including a dehumidification device and a deodorization device, and includes a basic frame and a plurality of hexahedral inner and outer adsorption blocks. ing. The basic frame has a plurality of fins extending radially. The plurality of inner peripheral suction blocks are arranged circumferentially on the inner peripheral side of the basic frame. The plurality of outer peripheral suction blocks are disposed on the outer peripheral side of the inner peripheral suction block. Between the two adjacent fins, n (n ≧ 1) inner circumferential suction blocks and m (m ≧ n and m ≧ 2) outer circumferential suction blocks are arranged.
[0022]
In the suction rotor according to a third aspect , the m outer peripheral suction blocks are formed with connecting grooves on the side surfaces facing the adjacent outer peripheral suction blocks so as to face each other. Moreover, the connecting member which fits into the groove for connection of the adjacent outer periphery side adsorption | suction block is further provided.
[0023]
When the outer peripheral block is divided and the number is larger than the inner peripheral block, there is a block in which only one side surface abuts against the adjacent fin or neither side surface abuts. In such a configuration, since each outer peripheral block is not sufficiently supported from the fins, it may be detached from the frame when it is attached to the suction device and receives strong wind pressure in the suction zone or the like.
[0024]
Therefore, in this suction rotor, a connecting groove is provided between adjacent suction blocks, and a connecting member is fitted into the connecting groove to increase the connecting force between adjacent blocks, and when the dehumidifier is in operation. Even if a strong wind pressure is applied, it is possible to avoid falling off between the fins.
[0025]
A suction rotor according to a fourth aspect is the suction rotor according to the third aspect , wherein a gap for expansion absorption is secured between two adjacent rotors connected by a connecting member.
[0026]
Even if the size of the outer peripheral block is reduced as a result of the division, some expansion occurs due to absorption of heat or moisture.
[0027]
Therefore, in this suction rotor, a gap is provided between adjacent suction blocks to absorb such expansion and suppress the pressing force from acting on the side surface of the block, thereby suppressing the occurrence of cracks. ing.
[0028]
An adsorption rotor according to a fifth aspect of the present invention has a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device, and includes a basic frame and a plurality of hexahedral adsorption blocks. The basic frame has a plurality of fins extending radially. The plurality of suction blocks are arranged in the circumferential direction between two adjacent fins of the basic frame.
[0029]
In this adsorption rotor, by dividing a block between two adjacent fins and reducing the size of each, the degree of expansion due to heat or moisture absorption can be reduced and the occurrence of cracks can be suppressed.
[0030]
Further, the adsorption rotor according to claim 5, further comprising a unit frame for accommodating a suction block multiple as 1 unit.
[0031]
Here, the same effects as claim 1 can be obtained.
[0032]
A suction rotor according to a sixth aspect is the suction rotor according to the fifth aspect, wherein a positioning portion for positioning in the rotor axial direction is formed on a surface of the unit frame that faces the suction block. The plurality of suction blocks are formed with engaging portions that engage with the positioning portions of the unit frame.
[0033]
Here, the same effect as that of the second aspect can be obtained.
[0034]
An adsorption rotor according to a seventh aspect of the present invention has a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device, and includes a basic frame and a plurality of hexahedral adsorption blocks. The basic frame has a plurality of fins extending radially. The plurality of suction blocks are arranged in the circumferential direction between two adjacent fins of the basic frame.
[0035]
Further, in the adsorption rotor according to claim 7, the adsorption block of multiple is the side facing the adjacent outer peripheral side suction block is connected groove is formed so as to face each other. Moreover, the connecting member which fits into the groove for connection of the adjacent outer periphery side adsorption | suction block is further provided.
[0036]
Here, the same effect as that of the second aspect can be obtained.
[0037]
The suction rotor according to an eighth aspect is the suction rotor according to the seventh aspect , wherein a gap for expansion absorption is secured between two adjacent rotors connected by the connecting member.
[0038]
Here, the same effect as that of the fourth aspect can be obtained.
[0039]
A suction device according to a ninth aspect is a device including a dehumidifying device and a deodorizing device, and includes a suction rotor, a casing, and a partition wall. The adsorption rotor is one of claims 1 to 8 . In the casing, the suction rotor is accommodated rotatably. The partition wall is formed in the casing with an adsorption portion formed on both sides in the axial direction of a partial circumferential region of the adsorption rotor and a reproduction unit formed on both sides in the axial direction of another circumferential region of the adsorption rotor. Is provided.
[0040]
In this suction device, since the size of the block arranged between the two adjacent fins is small, the degree of expansion of each block is small, thereby suppressing the occurrence of cracks.
[0041]
DETAILED DESCRIPTION OF THE INVENTION
[Overall configuration of dehumidifier]
FIG. 1 shows a dehumidifying device according to an embodiment of the present invention.
[0042]
This dehumidifying device is a device for adsorbing moisture in the air and sending out dry air, and includes a casing 1, partition walls 3 a and 3 b, blowers 5 and 6, and a dehumidifying rotor 2. .
[0043]
The casing 1 is a frame body in which the dehumidifying rotor 2 is rotatably housed. A motor 4 for rotationally driving the dehumidifying rotor 2 is disposed in the casing 1.
[0044]
The partition walls 3 a and 3 b are plate-like portions provided in the casing 1 so as to separate the dehumidification zone T and the regeneration zone R from each other. The dehumidifying zone T is formed on both axial sides of a part of the circumferential region of the dehumidifying rotor 2, and the regeneration zone R is formed on both axial sides of the other circumferential region of the dehumidifying rotor 2. Between the partition walls 3 a and 3 b and the dehumidifying rotor 2, a sealing material 8 for preventing air leakage between the zones T and R is provided. The sealing material 8 has flexibility, and the tip part is in contact with the surfaces on both axial sides of the dehumidifying rotor 2. A similar sealing material 8 is also provided between the partition wall 11, the standing wall 9 and the casing inner surface 1 a in the casing 1, and the dehumidifying rotor 2.
[0045]
The blowers 5 and 6 are used to blow air in the dehumidification zone T and the regeneration zone R formed in the casing 1, and are provided on the exit sides (T2 and R2) of the zones T and R, respectively. ing. These blowers 5 and 6 may be provided on the inlet side (T1, R1) with respect to the dehumidifying rotor 2. A heater 7 is provided at the intake of the regeneration air A5 in the regeneration zone R, and preheats the air blown into the dehumidifying rotor 2.
[0046]
In the dehumidifying device configured as described above, moisture-containing air A1 is first guided to the dehumidifying zone T1 by the operation of the blower 5, and passes through the dehumidifying rotor 2 rotated by the motor 4 in the axial direction. At this time, moisture in the air is removed from the air by being adsorbed by the dehumidifying rotor 2, and dried air A2 blows out in the dehumidifying zone T2. As a result, dry air is supplied into the room.
[0047]
Then, the dehumidification rotor 2 that has adsorbed moisture rotates and moves to the regeneration zone R, and the regeneration air A3 preheated from the opposite direction to the dehumidification zone is sent. Thereby, moisture is expelled from the dehumidifying rotor 2 that has adsorbed moisture into the outside air A4, and the dehumidifying rotor 2 is regenerated.
[0048]
[Dehumidification rotor]
Next, the dehumidifying rotor 2 will be described.
[0049]
The dehumidifying rotor 2 is a cylindrical rotating body of about φ4200 with the rotation shaft 2d as the center of rotation, and includes a basic frame 31 and a plurality of blocks 23, 25, 27 as shown in FIG.
[0050]
The basic frame 31 includes an inner peripheral frame 32, a plurality of fins 33 extending radially from the inner peripheral frame 32, and an outer peripheral frame 34. A plate 35 for preventing the blocks 23, 25, 27 from coming off is fixed to the end face in the axial direction of the fin 33 by a hexagon bolt 36. Between the two fins 33 adjacent to each other in the circumferential direction, one inner peripheral block 23, two middle outer peripheral blocks 25, and three outermost peripheral blocks 27 are arranged.
[0051]
The blocks 23, 25, and 27 are made of special paper obtained by special molding of activated carbon, silica gel, ceramic, or the like. As a result, the blocks 23, 25, and 27 have a structure in which corrugated cardboard formed by alternately sticking corrugated paper and flat paper made of special paper is laminated on a concentric circle around the rotation axis 2d. is doing. The blocks 23, 25, and 27 have a large number of ventilation holes that pass from the one end surface 2 a of the dehumidification rotor 2 to the other end surface 2 b, and a dehumidifying agent such as lithium chloride is added thereto.
[0052]
The outermost peripheral block 27 is formed so as to be disposed in the region of φ3000 to φ4200 of the dehumidifying rotor 2, and the middle outer peripheral block 25 is formed so as to be disposed in the region of φ2000 to φ3000 of the dehumidifying rotor 2. The side block 23 is formed so as to be arranged in a region of less than φ2000 of the dehumidifying rotor 2. Here, the six blocks 23, 25, 27 disposed between the two adjacent fins 33 are formed so that the surface areas on both sides in the axial direction are substantially equal to each other. Further, both end portions in the axial direction of the side surfaces adjacent to the fins 33 of the blocks 23, 25, and 27 are partly cut out and locked to the plate 35 of the basic frame 31 to be prevented from coming off. Yes.
[0053]
The outermost peripheral block 27 is a block disposed on the outermost peripheral side, and three blocks are disposed in the circumferential direction between the two fins 33. The three blocks 27 (see FIG. 4) are accommodated inside the unit frame 51 shown in FIG. Each of the three blocks 27 is formed with a connecting groove 27 b facing each other on a side surface 27 a facing the other adjacent block 27. When the connecting member 52 is fitted into the connecting groove 27b, adjacent blocks 27 in the unit frame 51 are connected to each other. As the connecting member 52, a commonly used square pipe is used. Further, an expansion absorbing gap S is secured between two adjacent blocks 27 connected by the connecting member 52.
[0054]
A positioning portion 51b for positioning the block 27 in the rotor axial direction is formed on the surface 51a of the unit frame 51 facing the block 27. The block 27 is formed with an engaging portion 27 c that engages with the positioning portion 51 b of the unit frame 51.
[0055]
The middle outer peripheral block 25 is a block disposed between the outermost peripheral block 27 and the inner peripheral block 23, and is disposed between two adjacent fins 33 in the circumferential direction. The two blocks 25 are arranged between two adjacent fins 33 in a state of being housed in a unit frame similar to the unit frame 52. Each of the two blocks 25 is formed with a connecting groove similar to the connecting groove 27b on the side surface facing the other adjacent middle / outer peripheral block 25 so as to face each other.
[0056]
The inner peripheral block 23 is arranged circumferentially on the innermost peripheral side of the basic frame 21.
[0057]
When the dehumidifying rotor 2 is attached to the dehumidifying device and operated, the block absorbs moisture in the dehumidifying zone and high-temperature air is blown in the regeneration zone, so that the block expands. Then, the block may be cracked due to the pressing force due to the reaction from the basic frame such as the fin.
[0058]
However, in the dehumidification rotor 2 configured as described above, between the adjacent two fins 33, the inner peripheral block 23, the intermediate outer peripheral block 25 that is larger in number than the inner peripheral block 23, and further More outermost blocks 27 than the number of the inner and outer blocks 25 are arranged. According to such a configuration, the size of the blocks arranged on the outer peripheral side can be reduced, and as a result, the degree of expansion of each block 23, 25, 27 can be reduced to suppress the occurrence of cracks. it can.
[0059]
Further, in this dehumidifying rotor 2, a connecting groove is provided between adjacent blocks, and a connecting member is fitted into this connecting groove, thereby increasing the connecting force between adjacent blocks and strong when the dehumidifying device is in operation. Even if wind pressure is received, it is possible to avoid falling off between the fins 33.
[0060]
Furthermore, in this dehumidifying rotor 2, by providing a gap between adjacent blocks, the expansion of each block due to absorption of heat or moisture is absorbed, so that the pressing force acts on the side surface of the block, thereby In order to suppress the occurrence of cracks.
[0061]
Moreover, in this dehumidification rotor 2, the outer peripheral block is housed as a unit in the unit frame, thereby improving handling during transportation and facilitating the work during assembly.
[0062]
Further, the dehumidification rotor 2 is positioned stably by the seal member when the dehumidification rotor is attached to the dehumidifying device by positioning the axial position of each block with respect to the unit frame body so as to keep both axial surfaces of the dehumidification rotor in the surface position A sealing effect is obtained.
[0063]
[Other Embodiments]
(A) In the said embodiment, the number of inner peripheral side blocks should just be fewer than an outer peripheral side block, and two or more may be arrange | positioned between two adjacent fins.
[0064]
(B) The block between two adjacent fins is not limited to the one divided in the radial direction as in the above embodiment, but is one divided in the circumferential direction as shown in FIG. Also good. Also in this case, by providing the above-described connecting groove and connecting member, positioning portion, engaging portion, etc., the inconvenience caused by dividing the block can be solved, and the same effects as the above embodiment can be obtained. can get.
[0065]
(C) The adsorption device of the present invention is not limited to a dehumidifying device, and other adsorption devices such as a deodorizing device may be used.
[0066]
【The invention's effect】
According to the present invention, between the two adjacent fins, the inner peripheral block and the outer peripheral blocks that are larger in number than the inner peripheral blocks are arranged. According to such a configuration, it is possible to reduce the size of the blocks arranged on the outer peripheral side, thereby suppressing the degree of expansion of each block and suppressing the occurrence of cracks.
[Brief description of the drawings]
FIG. 1 is a schematic longitudinal sectional view showing a dehumidifying device according to an embodiment of the present invention.
FIG. 2 is a schematic II-II cross-sectional view of the dehumidifier.
FIG. 3 is a schematic plan view of a dehumidifying rotor used in the dehumidifying device.
FIG. 4 is a perspective view of a main part showing a dehumidifying block of the dehumidifying rotor.
FIG. 5 is a main part perspective view showing a dehumidifying block and a unit frame of the dehumidifying rotor.
FIG. 6 is a schematic plan view of a dehumidification rotor according to another embodiment of the present invention.
[Explanation of symbols]
2 Suction rotor 23 Inner peripheral side suction block 25, 27 Outer peripheral side suction block 25b, 27b Connecting groove 27c Engaging portion 31 Basic frame 33 Fin 51 Unit frame 51b Positioning portion 52 Connecting member S Gap

Claims (9)

An adsorption rotor having a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device,
A basic frame having a plurality of radially extending fins;
A plurality of hexahedral inner suction blocks arranged circumferentially on the inner peripheral side of the basic frame, and a plurality of hexahedral outer suction blocks arranged on the outer peripheral side of the inner suction block With
Between the two adjacent fins, n (n ≧ 1) inner circumferential suction blocks and m (m ≧ n) outer circumferential suction blocks are arranged,
A unit frame for storing the m outer peripheral suction blocks as one unit;
Adsorption rotor. A positioning portion for positioning in the rotor axial direction is formed on the surface of the unit frame that faces the outer peripheral suction block,
The m outer peripheral suction blocks are formed with engaging portions that engage with the positioning portions of the unit frame.
The adsorption rotor according to claim 1. An adsorption rotor having a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device,
A basic frame having a plurality of radially extending fins;
A plurality of hexahedral inner suction blocks arranged circumferentially on the inner peripheral side of the basic frame, and a plurality of hexahedral outer suction blocks arranged on the outer peripheral side of the inner suction block With
Between two adjacent fins, n (n ≧ 1) inner circumferential suction blocks and m (m ≧ n and m ≧ 2 ) outer circumferential suction blocks are arranged,
The m outer peripheral suction blocks have coupling grooves formed on the side surfaces facing the adjacent outer peripheral suction blocks so as to face each other.
A connecting member that fits into the connecting groove of the adjacent outer peripheral suction block;
Adsorption rotor.   The suction rotor according to claim 3, wherein a gap for expansion absorption is secured between two adjacent suction blocks connected by the connecting member. An adsorption rotor having a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device,
A basic frame having a plurality of radially extending fins;
A plurality of hexahedral adsorbing blocks arranged in a circumferential direction between two adjacent fins of the basic frame;
A unit frame housing the plurality of suction blocks as one unit;
Adsorption rotor with A positioning portion for positioning in the rotor axial direction is formed on the surface of the unit frame that faces the suction block,
The plurality of suction blocks are formed with engaging portions that engage with the positioning portions of the unit frame.
The adsorption rotor according to claim 5. An adsorption rotor having a diameter of 2 m or more used in an adsorption device including a dehumidifying device and a deodorizing device,
A basic frame having a plurality of radially extending fins;
A plurality of hexahedral adsorbing blocks arranged in a circumferential direction between two adjacent fins of the basic frame;
The plurality of suction blocks have coupling grooves formed on the side surfaces facing the adjacent suction blocks so as to face each other.
A connecting member that fits into the connecting groove of the adjacent suction block;
Adsorption rotor.   The suction rotor according to claim 7, wherein a gap for expansion absorption is secured between two adjacent suction blocks connected by the connecting member. An adsorption device including a dehumidifying device and a deodorizing device,
An adsorption rotor according to any one of claims 1 to 8,
A casing in which the suction rotor is rotatably stored;
In the casing, a suction portion formed on both axial sides of a circumferential region of a portion of the suction rotor and a regeneration portion formed on both axial sides of another circumferential region of the suction rotor are formed. A partition wall provided to
Adsorption device with.

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