JP6415277B2 - Air conditioner for vehicles - Google Patents

Description

  The present invention relates to an air conditioner for a vehicle.

  Patent Document 1 discloses a vehicle air conditioner in which a hygroscopic device is disposed on a flow path of conditioned air.

Japanese Patent Laid-Open No. 08-67136

  The moisture absorber of this air conditioner is configured by combining a moisture absorbent (desiccant material) and a regeneration heater, and adsorbs moisture contained in the conditioned air flowing through the flow path to the moisture absorbent. When the hygroscopic material is saturated, the hygroscopic material is regenerated by heating the hygroscopic material with a regeneration heater to release moisture adsorbed on the hygroscopic material.

However, the air conditioner of Patent Document 1 has a configuration in which the conditioned air cannot be continuously dehumidified because the conditioned air cannot be dehumidified when the hygroscopic material is regenerated.
Therefore, in a vehicle air conditioner in which a hygroscopic material (desiccant material) is disposed in a flow path of conditioned air, it is required to continuously dehumidify the conditioned air.

The present invention
In a vehicle air conditioner configured to adsorb moisture contained in conditioned air flowing through a flow path of conditioned air to a desiccant material disposed on the flow path of conditioned air, and to dehumidify the conditioned air,
A flow path for the regeneration fluid for desorbing moisture from the desiccant material is provided separately from the flow path for the conditioned air,
The desiccant material was provided across the flow path of the conditioned air and the flow path of the regeneration fluid.

With this configuration, in the desiccant material, the amount of moisture adsorbed in the region in contact with the conditioned air is larger than the amount of moisture adsorbed in the region in contact with the regeneration fluid. The action of making it uniform is exhibited, and the moisture adsorbed in the area in contact with the conditioned air moves toward the area in contact with the regeneration fluid.
Here, in the region of the desiccant material in contact with the regeneration fluid, moisture is desorbed, so the amount of moisture adsorption in the region in contact with the regeneration fluid is less than the amount of moisture adsorption in the region in contact with the conditioned air. It will continue to be kept in quantity.
Therefore, the moisture adsorbed in the area in contact with the conditioned air always moves to the area in contact with the regeneration fluid, so that the amount of moisture adsorbed in the area in contact with the conditioned air reaches the upper limit and the dehumidification of the conditioned air is reduced. Since it cannot be disabled, the conditioned air can be dehumidified continuously.

It is a schematic block diagram of the air conditioner for vehicles concerning a 1st embodiment. It is a figure explaining the structure around the desiccant material of the air conditioner for vehicles concerning 1st Embodiment. It is a figure explaining the desiccant material concerning 1st Embodiment. It is a schematic block diagram of the air conditioner for vehicles concerning 2nd Embodiment. It is a figure explaining the desiccant material concerning 2nd Embodiment. It is a figure explaining the desiccant material concerning 2nd Embodiment. It is a figure explaining the desiccant material concerning a modification.

Hereinafter, a first embodiment of the present invention will be described.
FIG. 1 is a schematic configuration diagram of a vehicle air conditioner 1, and FIG. 1A is a diagram for explaining the arrangement of the vehicle air conditioner 1 in the vehicle V and the schematic configuration of the air conditioner 1. ) Is an enlarged view of a region A in FIG.
FIG. 2 is a diagram for explaining the arrangement of the desiccant material 30, and FIG. 2A is a diagram for explaining the arrangement of the desiccant material 30 provided across the differential duct 16 and the duct 20 of the air conditioner 1. FIG. 5 is a diagram in which a part of the differential duct 16, the duct 20, and the desiccant material 30 is cut away, and FIG. 5B illustrates the passing direction of the conditioned air and the regeneration fluid in the desiccant material 30 and the moving direction of moisture. FIG. 6 is a schematic view corresponding to a view in which the periphery of the desiccant material 30 is cut along a surface A in FIG.

  The air conditioner 1 adjusts conditioned air supplied to the passenger compartment 90 (temperature-adjusted air), an evaporator 12 that cools air blown from the blower 11, and air that has flowed in from the evaporator 12 side. And a mix door 14 that adjusts the amount of air cooled by the evaporator 12 to the heater core 13 side.

  In this air conditioner 1, the air cooled by the evaporator 12 and the air warmed via the heater core 13 are mixed in the mixing unit 15 to adjust the conditioned air at a predetermined temperature. The temperature of the conditioned air is adjusted by adjusting the amount of the cooled air flowing into the heater core 13 by the mix door 14.

  In the air conditioner 1, the conditioned air whose temperature is adjusted in the mixing unit 15 is supplied from a supply port (a differential side supply port 16 a, a front side supply port 17 a, a vent side supply port 18 a) that opens to the mixing unit 15 to a duct ( It is supplied into the passenger compartment 90 through the differential duct 16, the front duct 17, and the vent duct 18).

  In addition to these ducts (the differential duct 16, the front duct 17, and the vent duct 18), in addition to these ducts (the duct duct 16, the front duct 17, and the vent duct 18), the duct 20 through which the regeneration fluid flows is provided in the instrument panel P that partitions the casing 90 and the drive source PS accommodating portion 95. Is provided.

One end 20a of the duct 20 is located in the vicinity of the bonnet 96 in the housing portion 95 of the drive source PS (in the engine room when the drive source PS is an engine), and the rotary fan F attached to the duct 20 For example, the air in the housing portion 95 heated by the heat of the drive source PS is caused to flow into the duct 20.
Here, the end 20a of the duct 20 is positioned in the vicinity of the bonnet 96 because the air located between the drive source PS and the bonnet 96 has the highest temperature and low humidity due to the heat generated by the drive source PS. For this reason, in the embodiment, the air in the accommodating portion 95 sucked from the one end 20a of the duct 20 is used as the regeneration fluid.

The other end 20 b of the duct 20 is open to the outside of the vehicle V at a position below the vehicle compartment 90 of the vehicle V. The position at which the other end 20b of the duct 20 is opened is a space between the lower part of the vehicle body and the road surface that becomes negative pressure when the vehicle V travels.
Therefore, when the vehicle travels, the regeneration fluid in the duct 20 is sucked and discharged out of the duct 20 by the negative pressure generated in the space between the lower part of the vehicle body and the road surface.

Here, when the regeneration fluid in the duct 20 is discharged out of the duct 20, the air in the housing portion 95 is sucked from the one end 20 a of the duct 20 due to the differential pressure generated in the duct 20. The flow of the regeneration fluid in the duct 20 can be performed using the negative pressure when the vehicle travels.
Therefore, in the air conditioner 1 according to the embodiment, the regeneration fluid in the duct 20 can be passed even if the rotary fan F is omitted.

In the instrument panel P, there is a region where the duct 20 and the differential duct 16 are provided so that the wall portions 201 and 161 are in contact with each other.
In this region, there is a differential duct where the moving direction of the conditioned air flowing through the differential duct 16 and the moving direction of the regeneration fluid flowing through the duct 20 are parallel and opposite to each other. A desiccant material 30 described later is provided across the duct 16 and the duct 20.

The differential duct 16 is a cylindrical member that connects the air outlet 16b that opens near the lower portion of the windshield glass G and the differential side supply port 16a.
As shown in FIG. 2, the air outlet 16b has a predetermined length in the vehicle width direction so that the conditioned air blown from the air outlet 16b hits substantially the entire surface of the windshield glass G in the vehicle width direction. ing.
For this reason, the differential duct 16 connected to the air outlet 16b has a side surface shape in which the length in the vehicle width direction becomes longer as it approaches the air outlet 16b.

FIG. 3 is a diagram for explaining the desiccant material 30, and FIG. 3A is a diagram for explaining the arrangement of the desiccant material 30 provided across the differential duct 16 and the duct 20, and FIG. ) Is a diagram in which the periphery of the desiccant material 30 is cut along a plane B, and (b) is a diagram schematically illustrating the configuration of the desiccant material 30.
3A shows the internal space 162 of the differential duct 16 and the internal space 202 of the duct 20 that are located on the back side of the paper, with a part of the desiccant material 30 cut away.

As shown in FIG. 3 (a), the portion of the differential duct 16 where the desiccant material 30 is provided has a rectangular cross-sectional shape with long sides extending in the vehicle width direction, and the long side wall. The portion 161 is joined to the wall portion 201 of the regeneration fluid duct 20 over the entire length in the longitudinal direction (vehicle width direction).
Similarly, the portion of the duct 20 where the desiccant material 30 is provided also has a rectangular cross-sectional shape, and the portion of the duct 20 and the differential duct 16 where the desiccant material 30 is provided is the wall portion 161 of the differential duct 16 and the duct. The joint surface F1 with the 20 wall portions 201 extends in a straight line with a length extending over substantially the entire length in the vehicle width direction.

  In the portion where the desiccant material 30 is provided in the differential duct 16 and the duct 20, the length L2 in the direction perpendicular to the joint surface F1 of the internal space 162 of the differential duct 16 (the width in the direction perpendicular to the joint surface F1) is the joint surface F1. Is sufficiently shorter than the length L1 (the width in the direction along the joint surface F1) in the direction along the surface. Further, the length L3 in the direction orthogonal to the joint surface F1 of the internal space 202 of the duct 20 (the width in the direction orthogonal to the joint surface F1) is also the length L1 in the direction along the joint surface F1 (the direction along the joint surface F1). Is sufficiently shorter than the width.

  As shown in FIG. 2 (b), an internal space 162 of the differential duct 16 and an internal space 202 of the duct 20 are formed in a linear portion where the wall portions 161 and 201 of the differential duct 16 and the duct 20 are joined. Openings 161a and 201a to be communicated are provided with the same opening diameter, and these openings 161a and 201a have a predetermined length Lx in the direction along the joint surface F1.

The desiccant material 30 is provided through the openings 161a and 201a, and the thickness of the desiccant material 30 is the same as the length Lx of the openings 161a and 201a.
Furthermore, as shown to (a) of FIG. 3, the direction ((a) up-down direction of FIG. 3) along the joining surface F1 of the desiccant material 30, and the direction ((a) left-right of FIG. 3) orthogonal to the joining surface F1. The direction) is set to a size that can cover the entire cross section of the flow path cross section of the internal space 162 of the differential duct 16 and the cross section of the internal space 202 of the duct 20. The conditioned air flowing through and the regeneration fluid flowing through the duct 20 are moved across the desiccant material 30 in the direction along the joint surface F1.

As shown in FIG. 3B, the desiccant material 30 is disposed between a plurality of plate-like substrates 301 arranged in parallel with each other at a predetermined interval W1 and the plate-like substrate 301. And a corrugated substrate 302.
In the longitudinal direction of the corrugated substrate 302, the corrugated substrate 302 is alternately formed into a plate-shaped substrate 301 located on one side and the plate-shaped substrate 301 located on the other side across the corrugated substrate 302. It is provided in contact.
The contact portion between the corrugated substrate 302 and the plate-shaped substrate 301 is adhered by the adhesive 40, and the corrugated substrate 302 is positioned between the plate-shaped substrates 301 and 301 arranged in parallel to each other. The rigidity of the desiccant material 30 as a whole is increased.

  In the embodiment, the spaces S1 and S2 surrounded by the plate-like substrate 301 and the corrugated substrate 302 in the desiccant material 30 are flow paths (hereinafter referred to as spaces S1 and S2) through which conditioned air and regeneration fluid pass. The desiccant material 30 straddles the differential duct 16 and the duct 20 with the flow paths S1 and S2 along the moving direction of the conditioned air and the regeneration fluid. Is provided.

  Here, the base material between the plate-like base materials 301 and 301 arranged in parallel with each other is made corrugated, so that the total length of the corrugated base material 302 is larger than that of the plate-like base material 301. This is because, as a result of the lengthening, the chances of contact with the conditioned air and the regeneration fluid passing through the flow paths S1 and S2 increase, and the moisture exchange efficiency (adsorption and desorption efficiency) increases.

In the embodiment, the desiccant material 30 (plate-like base material 301, corrugated base material 302) is made of a material capable of adsorbing and desorbing moisture. Examples of such a material include non-woven fabric and paper. Illustrated.
Here, in order to improve the efficiency of adsorption and desorption, the plate-like base material 301 and the corrugated base material 302 have a moisture adsorbent such as a polymer adsorbent or sorbent or an inorganic adsorbent. A material capable of adsorption and desorption may be supported.
Further, instead of non-woven fabric or paper, for example, a polymeric adsorbent or sorbent is bound and formed into a plate shape or a corrugated shape so that the plate-like base material 301 and the corrugated base material 302 itself are formed. Alternatively, it may be composed of a polymeric adsorbent or a sorbent.

Hereinafter, an operation of the desiccant material 30 provided in the air conditioner 1 having such a configuration will be described.
In the vehicle V, when the inside of the passenger compartment 90 is air-conditioned without taking in outside air, the air conditioner 1 circulates the air taken in from the passenger compartment 90 into the passenger compartment 90 after temperature adjustment. Yes. Therefore, the humidity of the air to be circulated (air-conditioned air) increases with time according to the situation in the passenger compartment 90 and the like.

  Here, when air-conditioned air with high humidity is blown onto the windshield glass G, the windshield glass G may be clouded. Therefore, in the air conditioner 1 according to the embodiment, moisture contained in the conditioned air is adsorbed to the desiccant material 30 provided in the middle of the differential duct 16 to dehumidify the conditioned air blown to the windshield glass G.

Here, the desiccant material 30 is provided across the internal space 162 of the differential duct 16 and the internal space 202 of the duct 20, and the conditioned air flowing through the differential duct 16 is a region within the differential duct 16 in the desiccant material 30 ( It passes through the region R1) in FIG.
Therefore, when the conditioned air passes through the flow path S1 (see FIG. 3B) in the region R1 of the desiccant material 30, the plate-like base material 301 and the wave-like base material 302 surrounding the flow path S1 Moisture contained in the conditioned air is adsorbed to dehumidify the conditioned air.

  On the other hand, since the regeneration fluid that passes through the region (region R2 in FIG. 2B) located in the duct 20 of the desiccant material 30 is high-temperature air, the regeneration fluid is the region R2 of the desiccant material 30. The water adsorbed by the plate-like base material 301 and the corrugated base material 302 surrounding the flow path S2 when passing through the flow path S2 (see FIG. 3B) located in the plate-like base material It is desorbed from 301 and the corrugated substrate 302 and taken into the regeneration fluid.

Therefore, in the desiccant material 30, the amount of moisture adsorbed in the region R <b> 1 located in the differential duct 16 is larger than that in the region R <b> 2 located in the duct 20.
Here, in the desiccant material 30, the effect | action which equalizes the distribution of the water | moisture content in the desiccant material 30 whole is exhibited, and the water | moisture content adsorb | sucked by area | region R1 moves toward area | region R2.

  Therefore, in a state where the regeneration fluid and the conditioned air are continuously flowing, (1) the region R2 side where the moisture removed from the conditioned air and adsorbed to the region R1 of the desiccant material 30 has a small amount of moisture adsorption. (2) Since the moisture that has moved to the region R2 side is taken into the regeneration fluid that passes through the region R2, the amount of moisture adsorbed in the region R2 is always greater than the amount of moisture adsorbed in the region R1. It will be held in a small amount.

As a result, the moisture adsorbed in the region R1 of the desiccant material 30 always moves to the region R2 side, so that the amount of moisture adsorbed in the region R1 is not saturated.
Therefore, dehumidification of the conditioned air can be performed simply by continuously passing the regeneration fluid, so that the amount of moisture adsorbed on the desiccant material is saturated as in the case of conventional desiccant materials. No need to recycle the desiccant material

Here, as shown in FIG. 3B, in the desiccant material 30, the plate-like base material 301 and the corrugated base material 302 are joined surfaces F <b> 1 between the wall portion 161 of the differential duct 16 and the wall portion 201 of the duct 20. One end side of the plate-like base material 301 and the corrugated base material 302 is located in the flow path of the conditioned air (in the differential duct 16), and the other end side is in the flow path of the regeneration fluid. It is located (in the duct 20).
Therefore, the moisture adsorbed on one end side (region R1 side) of the plate-like substrate 301 and the corrugated substrate 302 always moves toward the other end side (region R2 side), and is adsorbed on one end side. Since the moisture moving direction is always on the other end side, the adsorbed moisture stays on the region R1 side, and it is possible to prevent a situation in which the moisture adsorption amount on the region R1 side is saturated.

Further, the adhesive 40 is interposed in the contact portion between the corrugated substrate 302 and the plate-shaped substrate 301, and the inside of the corrugated substrate 302 and the plate-shaped substrate 301 is directed from the region R1 side to the region R2 side. Moisture that moves in contact with the corrugated substrate 302 and the plate-shaped substrate 301,
Movement to the plate-like base material 301 side or the wave-like base material 302 side is prevented by the adhesive 40. Therefore, the moisture adsorbed in the region R1 on one end side of the corrugated substrate 302 and the plate-like substrate 301 can be quickly moved toward the region R2 on the other end side.
This also contributes to preventing the occurrence of a situation where the moisture adsorption amount on the region R1 side of the corrugated substrate 302 and the plate-like substrate 301 is saturated.

Furthermore, in the embodiment, the width L4 of the desiccant material 30 in the direction orthogonal to the joint surface F1 between the wall portion 161 of the differential duct 16 and the wall portion 201 of the duct 20 is sufficiently larger than the width L1 in the direction along the joint surface F1. The movement distance when the moisture adsorbed on the desiccant material 30 (the corrugated base material 302 and the plate-like base material 301) moves from the region R1 toward the region R2 is sufficiently short.
Therefore, since the moisture adsorbed in the region R1 can be moved to the region R2 in a short time and desorbed, it is possible to suitably prevent the moisture adsorbed on the desiccant material 30 from being saturated.

As described above, in the embodiment,
(1) A vehicle configured to dehumidify conditioned air by adsorbing moisture contained in conditioned air flowing through the diff duct 16 to a desiccant material 30 disposed on the diff duct 16 (flow path of conditioned air). In the air conditioner 1 for
A regeneration fluid duct 20 (regeneration fluid flow path) for desorbing moisture from the desiccant material 30 is provided separately from the differential duct 16, and
The desiccant material 30 is provided across the differential duct 16 and the duct 20, and the moisture adsorption amount in the region R1 in contact with the regeneration fluid in the desiccant material 30 is the moisture adsorption amount in the region R2 in contact with the conditioned air. Configured to be less.

If comprised in this way, in the desiccant material 30, the effect | action which tries to equalize the distribution of the water | moisture content in the desiccant material 30 whole will be exhibited, and the water | moisture content adsorb | sucked by area | region R1 which contacts the conditioned air of the desiccant material 30 will be shown. Then, it moves toward the region R2 in contact with the regeneration fluid.
Here, since moisture is desorbed in the region R2 in contact with the regeneration fluid in the desiccant material 30, the amount of moisture adsorption in the region R2 in contact with the regeneration fluid is the amount of moisture adsorption in the region R1 in contact with the conditioned air. Will continue to be kept in a smaller amount.
Therefore, in the desiccant material 30, the moisture adsorbed in the region R1 in contact with the conditioned air always moves toward the region R2 in contact with the regeneration fluid, so that the moisture adsorption amount in the region R1 in contact with the conditioned air reaches the upper limit. Therefore, the dehumidification of the conditioned air is not prevented, so that the dehumidification of the conditioned air can be performed continuously.
In particular, the desiccant material 30 utilizing adsorption causes water molecules to be adsorbed at the molecular level, and therefore has a weak binding force, and the movement of moisture in the desiccant material 30 is facilitated.

(2) The desiccant material 30 is configured such that the air-conditioning air differential duct 16 (flow path) and the regeneration fluid duct 20 (flow path) are brought into contact with each other so that the walls 161, 201 are in contact with each other. It is a region provided with the joint surface F1 in the direction along the vehicle width direction, and the moving direction of the conditioned air flowing through the differential duct 16 and the moving direction of the regeneration fluid flowing through the duct 20 are as follows. , Provided in parts parallel to each other and in opposite directions (contact part),
The cross-sectional shapes of the differential duct 16 and the duct 20 in the contact portion are rectangular in that the width L1 in the direction along the joint surface F1 between the wall portions 161 and 201 is larger than the widths L2 and L3 in the direction orthogonal to the joint surface F1. It was set as the structure which has a cross-sectional shape.

When configured in this way, the length in the direction (moisture movement direction) orthogonal to the joining surface F1 of the region R1 of the desiccant material 30 located in the differential duct 16 and the region R2 of the desiccant material 30 located in the duct 20 is set. Can be shortened.
Thereby, since the movement distance at the time of the water | moisture content adsorbed by the desiccant material 30 moving toward the area | region R2 from the area | region R1 of the desiccant material 30 becomes short, compared with the case where the movement distance of moisture is long, it is shorter. Thus, the moisture can be moved from the region R1 to the region R2, and the moisture adsorption amount in the region R1 located in the flow path of the conditioned air can be kept without being saturated.

  Further, since the direction along the joint surface F1 is the vehicle width direction, the differential duct 16 and the duct 20 are wide in the direction along the joint surface F1 (vehicle width direction) and are orthogonal to the joint surface F1 (front and rear of the vehicle). (Direction) is a narrow cylindrical duct. Accordingly, the desiccant material 30 has a rectangular shape in which the width in the direction along the joint surface F1 (vehicle width direction) is wide and the width in the direction perpendicular to the joint surface F1 (vehicle longitudinal direction) is narrow. By effectively utilizing the width, it is possible to shorten the moving distance of moisture in the desiccant material 30 while ensuring the opportunity for the conditioned air and the regeneration fluid to contact the desiccant material 30. As a result, the regeneration time of the desiccant material 30 (the time required for the moisture adsorbed in the region R1 to move to the region R2) is shortened, so that the amount of moisture adsorbed in the region R1 in contact with the conditioned air reaches the upper limit. Air conditioning air can not be dehumidified.

(3) The desiccant material 30 is disposed along the moving direction of the conditioned air and the regeneration fluid across the wall portion 161 of the differential duct 16 and the wall portion 201 of the duct 20 in a direction orthogonal to the joint surface F1. , A plurality of plate-like base materials 301 provided at predetermined intervals in the direction along the joint surface F1, and
Between the plate-like base materials 301 and 301 adjacent in the direction along the joint surface F1, the differential duct 16 and the duct 20 are crossed in a direction perpendicular to the joint surface F1, and along the moving direction of the conditioned air and the regeneration fluid. And a wavy substrate 302 formed in a waveform when viewed from the moving direction.
Between the plate-like base materials 301 and 301 adjacent in the direction along the joint surface F1, the corrugated base material 302 is divided into one plate-like base material 301 and the other plate-like base material 301 in the direction along the joint surface F1. Channels S1 and S2 through which air-conditioned air and regeneration fluid pass are formed between the plate-like substrate 301 and the wave-like substrate 302, and the plates in the wave-like substrate 302 are provided alternately. The adhesive 40 is interposed at the contact point with the substrate 301.

If comprised in this way, since the corrugated base material 302 will function as a rib which raises rigidity strength, the rigidity strength of the desiccant material 30 will improve.
Further, the corrugated substrate 302 has a longer overall length in the direction orthogonal to the joining surface F1 than the plate-shaped substrate 301, and the contact area (opportunity) with the conditioned air or the regeneration fluid passing through the flow paths S1 and S2 is Since it is larger (larger) than the plate-shaped substrate 301, it is possible to more efficiently adsorb moisture from the conditioned air and release the adsorbed moisture.

Further, since the adhesive 40 is present at the contact point between the corrugated substrate 302 and the plate-like substrate 301, the plate-like substrate 301 and the corrugated substrate 302 are moved from the region R1 on the differential duct 16 side to the duct 20 side. Since the moving direction of the water that is moving toward the region R2 is not disturbed at the contact point between the corrugated substrate 302 and the plate-like substrate 301, the moisture is directed toward the region R2 in contact with the regeneration fluid. It is possible to reliably move and desorb moisture from the desiccant material 30.
In addition, by giving the waterproof property to the adhesive 40, it is possible to move the moisture more reliably toward the region R2 in contact with the regeneration fluid.

(4) The suction port of the one end 20a of the duct 20 is opened into the accommodating portion 95 that accommodates the drive source PS of the vehicle V on which the air conditioner 1 is mounted, and the regeneration fluid is taken in from the accommodating portion 95. It was hot air.

If comprised in this way, since the inside of the accommodating part 95 (engine room) in which the drive source PS (for example, engine) of the vehicle V is accommodated becomes high temperature, the air taken in from this engine room is made into the fluid for reproduction | regeneration. The high-temperature air will pass through the desiccant material 30, and the moisture adsorbed on the desiccant material 30 can be more reliably desorbed.
Especially during the heating operation in winter, the air in the housing portion 95 becomes high temperature and low humidity, so that the moisture adsorbed on the desiccant material 30 can be more reliably obtained by using the high temperature and low humidity air as a regeneration fluid. Thus, the desorption of moisture is more reliable than when the outside air is used as a regeneration fluid.

  In addition, since it is not necessary to separately provide a heat source for increasing the temperature of the regeneration fluid, an increase in energy consumption in the vehicle V can be suppressed. As a result, in the case of a vehicle that employs a battery-driven motor as the drive source PS, a high-temperature regeneration fluid can be supplied without consuming battery power. Occurrence of a situation where the travelable distance decreases can be suitably prevented.

(5) The exhaust port of the other end 20b of the duct 20 is opened to a portion where negative pressure is generated when the vehicle below the vehicle V on which the air conditioner 1 is mounted, and the negative pressure during vehicle travel is used. Thus, the regeneration fluid in the duct 20 is moved.

If comprised in this way, since the regeneration fluid in the duct 20 can be moved using a negative pressure, it is not necessary to provide the rotary fan F etc. separately in order to move the regeneration fluid.
When the rotary fan F or the like is provided, it is necessary to supply electric power for driving the rotary fan F. However, in order to move the regeneration fluid by moving the regeneration fluid using the negative pressure during traveling. Does not need energy.
As a result, in the case of a vehicle that employs a battery-driven motor as the drive source PS, battery power is not consumed for the movement of the regeneration fluid, so the motor operating time is reduced and the vehicle travel distance is reduced. Occurrence of such a situation can be suitably prevented.

The second embodiment of the present invention will be described below.
FIG. 4 is a schematic configuration diagram of an air conditioner 1A that employs the desiccant material 30A according to the second embodiment. FIG. 4A illustrates the arrangement of the air conditioner 1A in the vehicle V and the schematic configuration of the air conditioner 1A. (B) is an enlarged view of region A in (a).

In the air conditioner 1A employing the desiccant material 30A according to the second embodiment, the differential duct 16 and the duct 20 are provided orthogonally in the instrument panel P, and at the intersection of the differential duct 16 and the duct 20. The desiccant material 30A is arranged.
In the air conditioner 1A, the difference between the differential duct 16 and the duct 20 and the configuration of the desiccant material 30A provided at the intersection between the differential duct 16 and the duct 20 are different from those of the air conditioner 1 described above. Therefore, in the following description, only different parts will be described, and description of common parts will be omitted.

FIG. 5 is a diagram for explaining the desiccant material 30A, (a) is a diagram for explaining the arrangement of the desiccant material 30A at the intersection between the differential duct 16 and the duct 20 of the air conditioner 1A, and (b). FIG. 10 is a diagram for explaining the moving direction of the conditioned air and the regeneration fluid in the desiccant material 30A, and (c) is a diagram for explaining a modification of the moving direction of the conditioned air and the regeneration fluid in the desiccant material 30B. It is a figure explaining the case where the differential duct 16 and the duct 20 are not orthogonally crossed.
FIG. 6 is a diagram for explaining the cylindrical base material 305 of the desiccant material 30A, (a) is a diagram for explaining the configuration of the cylindrical base material 305, and (b) is a diagram showing the cylindrical base material 305A, It is a figure explaining arrangement | positioning of 305B, it is the figure which separated and showed the cylindrical base materials 305A and 305B connected with the desiccant material 30A, and was shown partially cut away, (c) is a cylindrical base It is a figure explaining movement of moisture in materials 305A and 305B.

  As shown in FIG. 5A, at the intersection of the differential duct 16 and the duct 20, the moving direction of the conditioned air and the moving direction of the regeneration fluid are orthogonal to each other, and the desiccant 30A passes through the conditioned air. A plurality of cylindrical base materials 305 </ b> A and a cylindrical base material 305 </ b> B through which a regeneration fluid passes are connected in the width direction of the differential duct 16 and the duct 20.

  Here, since the cylindrical base material 305A and the cylindrical base material 305B have the same basic configuration, the cylindrical base material 305A and the cylindrical base material 305B are particularly distinguished in the following description. If not, it will be labeled as a cylindrical substrate 305 for convenience of explanation.

As shown in FIG. 6A, the cylindrical base material 305 includes a cylindrical base portion 306 having a rectangular shape in a cross-sectional view, and side portions 306a and 306a on the long sides parallel to each other of the cylindrical base portion 306. And a waveform base 307 disposed therebetween.
When viewed from the passing direction of the conditioned air (regeneration fluid), the corrugated base 307 is provided alternately in contact with the one side 306a and the other side 306a. A space S3 surrounded by 306 and the waveform base 307 is a flow path (hereinafter, this space S3 is referred to as a flow path S3) through which conditioned air and regeneration fluid pass.

  The desiccant material 30A is configured by connecting a plurality of cylindrical base materials 305. In the adjacent cylindrical base materials 305 and 305, the side portions 306a and 306a on the long side of each other are in contact with each other over the entire surface. ing.

In the embodiment, the desiccant material 30A includes a cylindrical base material 305A in which the opening of the flow path S3 is arranged along the moving direction of the conditioned air, and the opening of the flow path S3 along the moving direction of the regeneration fluid. In the desiccant material 30A shown in FIG. 5 (a), the cylindrical base material 305A and the cylindrical base material 305B are stacked in the stacking direction. Alternatingly arranged.
Therefore, in the desiccant material 30A in a side view, the flow path S3 of the cylindrical base material 305A (indicated by a dotted line in FIG. 5B) and the flow path S3 of the cylindrical base material 305B (in FIG. 5B) Are perpendicular to each other).

  Here, in the desiccant material 30A, the widths W1 and W2 (see FIG. 6B) in the stacking direction of the cylindrical base material 305A and the cylindrical base material 305B are set to the same width. The width W2 of the cylindrical base material 305B through which the air passes may be larger than the width W1 of the cylindrical base material 305A through which the conditioned air passes. In this case, the amount of moisture adsorbed on the cylindrical base material 305B of the desiccant material 30A can be further reduced by increasing the flow rate of the regeneration fluid, so that the moisture adsorbed on the cylindrical base material 305A side can be more quickly absorbed. Can be moved to the cylindrical base material 305B side.

When the moisture adsorption amount of the desiccant material 30A on the cylindrical base material 305B is further lowered, the width of the cylindrical base material 305A is not changed, but the cylindrical base material 305A and the cylindrical base material 305B are not changed. You may make it change a ratio. For example, by increasing the number of cylindrical base materials 305B in the desiccant material 30A more than the cylindrical base materials 305A, the amount of moisture adsorbed on the desiccant material 30A can be further reduced.
In the embodiment, the width L5 of the differential duct 16 and the width L4 of the duct 20 at the intersection are the same, and the widths W1 and W2 in the stacking direction of the cylindrical base material 305A and the cylindrical base material 305B are changed. However, the amount of moisture adsorbed on the cylindrical base material 305B of the desiccant material 30A is adjusted more easily than changing the width of the differential duct 16 and the duct 20 at this intersection, and the cylindrical base material 305A side is adjusted. Moisture adsorption can be performed more quickly and continuously.

Hereinafter, the operation of the desiccant material 30A included in the air conditioner 1A having such a configuration will be described.
In the cylindrical base material 305 </ b> A, the conditioned air passes through the flow path S <b> 3 surrounded by the cylindrical base 306 and the waveform base 307.
Therefore, when the conditioned air passes through the cylindrical base material 305A, moisture contained in the conditioned air is adsorbed by the cylindrical base 306 and the waveform base 307 surrounding the flow path S3, and the conditioned air is dehumidified. .
On the other hand, in the cylindrical base material 305B through which the regeneration fluid passes, since the regeneration fluid is high-temperature air, the moisture adsorbed on the tubular base portion 306 and the corrugated base portion 307 surrounding the flow path S3 is tubular. It is detached from the base 306 and the waveform base 307 and taken into the regeneration fluid.

  Therefore, in the desiccant material 30A, the cylindrical base material 305A has a larger amount of moisture adsorbed than the cylindrical base material 305B. Therefore, the desiccant material 30A has an effect of making the moisture distribution in the entire desiccant material 30A uniform. As a result, moisture moves from the cylindrical base material 305A toward the cylindrical base material 305B adjacent to the cylindrical base material 305A.

Specifically, as shown in FIG. 6C, in the desiccant material 30A, the cylindrical base material 305A through which the conditioned air passes and the cylindrical base material 305B through which the regeneration fluid passes are arranged on the sides. Since it is provided in contact with the portion 306a, the moisture adsorbed on the side portion 306a of the cylindrical base material 305A quickly moves to the side portion 306a of the cylindrical base material 305B in contact with the side portion 306a.
Further, in the cylindrical base material 305 </ b> A, the corrugated base 307 is located inside the cylindrical base 306, and the corrugated base 307 is in contact with the side portions 306 a of the cylindrical base 306 alternately. For this reason, the moisture adsorbed on the corrugated base 307 moves to the side 306a of the cylindrical base 306 and then moves to the cylindrical base material 305B through which the regeneration fluid passes.
Therefore, by providing the corrugated base 307 inside the cylindrical base 306, the contact area with the conditioned air is increased, so that the moisture contained in the conditioned air is more reliably adsorbed and the conditioned air can be dehumidified.

  As described above, in a state where the regeneration fluid and the conditioned air are continuously flowing, (1) the moisture removed from the conditioned air and adsorbed on the tubular base material 305A has a small moisture adsorption amount. The moisture that has moved to the base material 305B side and (2) the moisture that has moved to the cylindrical base material 305B is taken into the regeneration fluid that passes through the cylindrical base material 305B. The amount of moisture adsorbed by the cylindrical base material 305A is always held in a smaller amount.

As a result, the moisture adsorbed on the cylindrical base material 305A of the desiccant material 30A always moves toward the cylindrical base material 305B, so that the amount of moisture adsorbed on the cylindrical base material 305A is not saturated. Become.
Therefore, unlike the case of conventional desiccant materials, the desiccant material does not need to be regenerated by saturation of the moisture adsorption amount. The dehumidification of can be performed continuously.
Therefore, the desiccant material (total heat exchange material) can be used at all times, and further, there is no need to provide a mechanism for switching the flow path of the conditioned air or the regeneration fluid, so a desiccant system with a simple configuration is realized.

(6) As described above, the desiccant material 30A is provided at a portion where the differential duct 16 through which the conditioned air flows and the duct 20 through which the regeneration fluid flows intersect.
Desiccant material 30A
A cylindrical base material 305A (first cylindrical base material) having a rectangular shape in a cross-sectional view and having a pair of side portions 306a and 306a facing each other with a gap therebetween,
A cylindrical base material 305B (second cylindrical base material) having a pair of side parts 306a and 306a facing each other with a rectangular shape in a cross-sectional view is formed by connecting the side parts 306a and 306a to each other. It is made up of a plurality of lines in contact with each other.
In the desiccant material 30A, the cylindrical base material 305A is arranged with the opening along the flow direction of the conditioned air, and the cylindrical base material 305B has the opening along the flow direction of the regeneration fluid. It was set as the structure arrange | positioned by direction.

With this configuration, the amount of moisture adsorbed in the cylindrical base material 305B through which the regeneration fluid flows is smaller than the amount of water adsorbed in the cylindrical base material 305A through which the conditioned air flows. The moisture of the air-conditioned air adsorbed by the cylindrical base material 305A moves to the cylindrical base material 305B adjacent to the cylindrical base material 305A, and is regenerated by the regeneration fluid passing through the cylindrical base material 305B. It is desorbed from the base material 305B.
The amount of water adsorbed on the cylindrical base material 305B through which the regeneration fluid flows continues to be kept smaller than the amount of water adsorbed on the cylindrical base material 305A through which conditioned air flows. Therefore, the moisture adsorbed on the cylindrical base material 305A always moves toward the cylindrical base material 305B through which the regeneration fluid flows, so that the moisture in the cylindrical base material 305A through which the conditioned air flows flows. Therefore, the air-conditioning air can be continuously dehumidified.

(7) Inside the cylindrical base material 305 (305A, 305B), a pair of sides facing each other with a corrugated base portion 307 formed into a corrugated shape as viewed from the flow direction of the conditioned air (regeneration fluid) The portion 306a and the other side portion 306a are alternately in contact with each other.

If comprised in this way, since the waveform base part 307 functions as a rib which raises the rigidity strength of the cylindrical base material 305, the rigidity strength of the desiccant material 30A comprised by connecting the cylindrical base material 305 will improve.
Moreover, since the waveform base 307 increases the contact area (opportunity) with the conditioned air or the regeneration fluid, it is possible to more efficiently perform the adsorption of moisture from the conditioned air and the release of the adsorbed moisture.
Furthermore, since the corrugated base 307 is alternately in contact with the one side 306a and the other side 306a, the moisture adsorbed on the corrugated base 307 can be quickly moved to the cylindrical base 306 side. Thereby, the water | moisture content adsorbed by the cylindrical base material 305 through which conditioned air passes can be rapidly moved to the cylindrical base material 305 side through which the regeneration fluid passes.

In the second embodiment described above, the desiccant material 30 </ b> A is illustrated as being provided at the intersection where the differential duct 16 and the duct 20 are orthogonal to each other, but the differential duct 16 and the duct 20 are not necessarily orthogonal to each other. Instead, for example, as shown in FIG. 5C, a desiccant material may be provided at an intersecting portion intersecting at a predetermined angle θ.
In this case, in the desiccant material 30B in a side view, the flow path S3 of the cylindrical base material 305A (indicated by a dotted line in FIG. 5C) and the flow path S3 of the cylindrical base material 305B (in FIG. c) (shown by a solid line) crosses at the same crossing angle as the crossing angle θ between the differential duct 16 and the duct 20. Also by doing in this way, the same operation effect as the case of the above-mentioned 2nd embodiment is produced.

Further, in the first embodiment described above, the case where the differential duct 16 and the duct 20 are in contact with each other's wall portions 161 and 201 has a rectangular cross-sectional shape, but FIG. As shown, the differential duct 16A and the duct 20A having an elliptical cross-sectional shape may be used.
Also in this case, the length L of the desiccant material 30 in the direction along the joint surface F1 between the differential duct 16A and the duct 20A is sufficiently longer than the length L4 in the direction orthogonal to the joint surface F1 as described above. The same effects as those in the embodiment are exhibited.

  Furthermore, in the first embodiment described above, the corrugated substrate 302 is provided in contact with the plate-shaped substrate 301 on one side and the plate-shaped substrate 301 on the other side alternately with the corrugated substrate 302 in between. In addition to this configuration, as shown in FIG. 7B, a corrugated substrate located on one side with the plate-shaped substrate 301 interposed therebetween is illustrated. It is good also as a structure which made the position where 302 contact | abuts the plate-shaped base material 301 and the position where the corrugated base material 302 located in the other side contact | abuts the plate-shaped base material 301 correspond.

  In such a case, the point of action of the stress acting on the plate-like substrate 301 from the wave-like substrate 302 is the same position in the longitudinal direction of the plate-like substrate 301, so that the plate from the wave-like substrate 302 located on one side is Even if the direction of the stress acting on the plate-like substrate 301 is opposite to the direction of the stress acting on the plate-like substrate 301 from the wave-like substrate 302 located on the other side, the stress is canceled and the plate-like substrate Since the linearity of the material 301 is maintained, the rigidity strength of the desiccant material 30 as a whole is increased.

Further, in the first embodiment described above, the case where the joint surface F1 between the wall portion 161 of the differential duct 16 and the wall portion 201 of the duct 20 is linear when viewed from above is illustrated. Need not be.
If the windshield glass G of the vehicle V is curved when viewed from above, the cross-sectional shapes of the differential duct 16 and the duct 20 are set so that the joint surface F1 along the curved surface of the windshield glass G is formed. good.

DESCRIPTION OF SYMBOLS 1, 1A Air conditioner 11 Blower 12 Evaporator 13 Heater core 14 Mix door 15 Mixing part 16, 16A Differential duct 16a Differential side supply port 16b Outlet 17 Front duct 18 Vent duct 20, 20A Duct 20a One end 20b The other end 30, 30A, 30B Desiccant Material 90 Car compartment 95 Accommodating part 96 Bonnet 161 Wall part 161a Opening 162 Internal space 201 Wall part 202 Internal space 301 Plate-like base material 302 Corrugated base material 305, 305A, 305B Cylindrical base material 306 Cylindrical base part 307 Waveform base part F Rotary Fan F1 Bonding surface G Windshield glass P Instrument panel PS Drive source

Claims (6)

In a vehicle air conditioner configured to dehumidify the conditioned air by adsorbing moisture contained in the conditioned air flowing through the conditioned air flow path to a desiccant material disposed on the conditioned air flow path ,
A flow path for the regeneration fluid for desorbing moisture from the desiccant material is provided separately from the flow path for the conditioned air,
The desiccant material is provided across the flow path of the conditioned air and the flow path of the regeneration fluid ,
An exhaust port of the flow path for the regeneration fluid is opened to a portion where negative pressure is generated when the vehicle is traveling, and the regeneration fluid is flown inside the flow path of the regeneration fluid using the negative pressure during vehicle travel. A vehicle air conditioner characterized in that fluid moves . The desiccant material is
The flow path of the conditioned air and the flow path of the regeneration fluid are brought into contact with each other, and the contact portion provided in a direction in which the joint surfaces of the wall portions are along the vehicle width direction. Provided,
The cross-sectional shape of the flow path of the conditioned air and the flow path of the regeneration fluid in the contact portion is:
2. The vehicle air conditioner according to claim 1, wherein a width in a direction along the joint surface between the wall portions has a cross-sectional shape larger than a width in a direction orthogonal to the joint surface. . The desiccant material is
The flow path of the conditioned air and the flow path of the regeneration fluid are arranged along the flow direction of the conditioned air and the regeneration fluid so as to cross in a direction perpendicular to the joint surface, and the joint surface A plurality of plate-like base portions provided at predetermined intervals in the direction along
Between the plate-like bases adjacent to each other in the direction along the joint surface, the conditioned air flow path and the regeneration fluid flow path cross in a direction perpendicular to the joint surface so as to cross the conditioned air and the regeneration base. A corrugated base that is disposed along the flow direction of the fluid and that is formed into a wave shape when viewed from the flow direction;
Have
Between the plate-like bases adjacent to each other in the direction along the joint surface, the corrugated base is provided alternately in contact with one plate-like base and the other plate-like base in the direction along the joint surface. The vehicle air conditioner according to claim 2, wherein an adhesive is interposed at a contact point between the corrugated base and the plate-like base. The desiccant material is
The conditioned air flow path and the regeneration fluid flow path are provided at intersecting portions,
The desiccant material is
A first cylindrical base portion having a pair of side wall portions facing each other at an interval;
A plurality of second cylindrical base portions having a pair of side wall portions facing each other with a gap between them, and in a state where the side wall portions are in contact with each other.
In the desiccant material, the first cylindrical base portion is provided in a direction along an opening in the flow direction of the conditioned air, and the second cylindrical base portion is a flow direction of the regeneration fluid. The air conditioner for a vehicle according to claim 1, wherein the air conditioner is provided in a direction along the opening. Inside the first cylindrical base, a pair of first corrugated bases formed in a waveform as viewed from the flow direction of the conditioned air are opposed to each other with the gap between the first cylindrical bases. Provided in alternating contact with one and the other of the side walls,
Inside the second cylindrical base, a pair of second corrugated bases formed in a corrugated shape as viewed from the flow direction of the regeneration fluid are opposed to each other with the gap between the second cylindrical bases. 5. The vehicle air conditioner according to claim 4, wherein the vehicle air conditioner is provided in contact with one and the other of the side wall portions alternately. The inlet of the flow path for the regeneration fluid is opened in a storage chamber in which the drive source of the vehicle equipped with the air conditioner is accommodated, and the regeneration fluid is made into hot air taken in from the storage chamber The vehicle air conditioner according to any one of claims 1 to 5, characterized in that

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