JP2019151245A - Seat air-conditioner and seat air-conditioning system - Google Patents

Abstract

To provide a seat air-conditioner and so on that, when an occupant leaves a seat, are able to early recover seat comfortability that has decreased due to seating.SOLUTION: A seat air-conditioner 1 is applied to a seat 30 that an occupant P can sit on. In a seating surface part 31 of the seat 30, a lower ventilation passage 10 and a first blower 15 are arranged. A current of ventilation air A passed through the lower ventilation passage 10 is sent via a lower cushion part 31A by operation of the first blower 15. In a backrest part 32 of the seat 30, an upper ventilation passage 20 and a second blower 25 are arranged. A current of blowing air A passed through the upper ventilation passage 20 is sent via an upper cushion part 32A by operation of the second blower 25. In a case where it is detected that an occupant P seated on the seat 30 has left there, the first blower 15 and the second blower 25 are operated to decrease the surface temperature Ts of a lower cushion part 31A or the like, which has arisen due to the body temperature and so on of the seated occupant P.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a seat air conditioner and a seat air conditioning system that improve comfort in a seat.

  Conventionally, there is air between the occupant seated on the seat and the surface of the seat, which is warmed by the occupant's body temperature and is steamed by the sweat of the occupant. This hot and humid air reduces the comfort of the passenger sitting on the seat.

  As a technique for solving this problem, the invention described in Patent Document 1 is known. The seat ventilation apparatus described in Patent Document 1 uses a vacuum suction device to suck air from the surface of a breathable seat and ventilate the steamed air present on the seat surface.

  And in the seat ventilation apparatus described in patent document 1, the decompression suction machine is arrange | positioned outside the vehicle, the air of the surface of a sheet | seat is attracted | sucked outside the vehicle using the flow of the air at the time of driving | running | working of a vehicle. It is configured to exhaust.

JP 2004-097748 A

  Here, the steamed air due to the seating of the occupant continues to stay on the surface of the seat not only when the occupant is seated on the seat but also when the occupant leaves the seat. Therefore, if a new occupant sits on the seat immediately after the occupant leaves the seat, the comfort of the newly seated occupant decreases due to the air heated by the body temperature of the occupant who has left the seat. It is assumed that

  In the seat ventilation apparatus described in Patent Document 1, the vacuum suction device is operated using the air flow accompanying the traveling of the vehicle, and the steam on the seat surface is discharged outside the vehicle. This is a precondition for restoring seat comfort.

  Therefore, in the seat ventilation apparatus of Patent Document 1, the comfort of the seat cannot be recovered unless the vehicle is traveling at the timing when the occupant leaves the seat. That is, with the technique of Patent Document 1, it is difficult to restore the comfort of the seat as the person leaves the seat.

  The present invention has been made in view of these points, and provides a seat air conditioner that can quickly recover the comfort of a seat that has been lowered due to seating when the occupant leaves the seat. Objective.

  The present invention also relates to a seat air-conditioning system having a seat air-conditioning device and a vehicle air-conditioning device, wherein when a passenger leaves the seat, the seat air-conditioning system capable of quickly recovering the comfort of the seat that has been lowered due to the seating. The second purpose is to provide it.

In order to achieve the object, the seat air-conditioning apparatus according to claim 1,
A seat (30) provided with seat surface portions (31A, 32A) having contact with the seated seated person (P) and having air permeability;
Blowers (15, 25) for blowing air through the sheet surface portion;
Inside the seat, connecting the blower to the surface of the seat, the ventilation path (10, 20) through which the air by the operation of the blower flows,
A seating detection unit (51) for detecting a seated person seated on the seat;
A control unit (50) for controlling the operation of the blower,
The control unit
An absence determination unit (50A) for determining whether or not a seated person has left the seat according to a change in a detection result by the seating detection unit;
A blow control unit (50B) for controlling the operation of the blower so that air is blown through the surface of the seat when it is determined that the seated person has left the seat.

  In the seat air conditioner, the seat is configured so that a seated person can sit. For this reason, when the seated person is seated on the seat, the seat surface portion is assumed to be warmed and steamed by the body temperature, sweating, etc. of the seated person.

  According to the seat air conditioner, when it is determined by the absence determination unit that the seated person has left the seat, the blower is operated to blow air through the seat surface portion. Thereby, the said seat air conditioner can exclude the steamed air warmed by the body temperature etc. of the seated person who left the seat from the seat surface portion.

  That is, according to the seat air conditioner, when the seated person leaves the seat, the comfort of the seat that has been lowered due to the influence of the body temperature or the like of the seated person can be recovered by blowing with the blower. As a result, the seat air conditioner can provide a comfortable seat that is not affected by the warmth or stuffiness of the previous seated person.

The seat air conditioning system according to claim 11
An air conditioner for a vehicle (40) for blowing conditioned air (CA) whose temperature is adjusted toward the inside of the passenger compartment (C) of the vehicle;
A seat air conditioner (1) that is disposed on a seat (30) disposed inside the passenger compartment and that performs air conditioning for a position of a seated person (P) seated on the seat;
A seating detection unit (51) for detecting a seated person seated on the seat;
A control device (60) for controlling the operation of the vehicle air conditioner and the seat air conditioner,
Seat air conditioner
Blowers (15, 25) for contacting the seated person seated on the seat and blowing air through the seat surface portions (31A, 32A) having air permeability,
In the interior of the seat, there is a ventilation path (10, 20) for connecting air from the blower to the surface of the seat and through which air is generated by the operation of the blower.
The control device
An absence determination unit (60A) for determining whether or not a seated person has left the seat according to a change in a detection result by the seating detection unit;
When the absence determination unit determines that the seated person has left the seat, the operation of the vehicle air conditioner is controlled so that the conditioned air is blown to the seat, and the air is blown through the seat surface portion. And an operation control unit (60B) for controlling the operation of the seat air conditioner.

  Also in the seat air conditioning system, the seat is configured so that a seated person can sit. For this reason, when the seated person is seated on the seat, the seat surface portion is assumed to be warmed and steamed by the body temperature, sweating, etc. of the seated person.

  According to the seat air conditioning system, when it is determined that the seated person has left the seat, the conditioned air is blown from the vehicle air conditioner to the seat. Thus, air is sent through the sheet surface portion.

  As a result, the seat air conditioning system can quickly remove the steamed air heated by the body temperature of the seated person away from the seat surface portion in cooperation with the seat air conditioner and the vehicle air conditioner. .

In other words, according to the seat air conditioning system, when the seated person leaves the seat, the seat air conditioner and the vehicle air conditioner are operated in a coordinated manner, so that the comfort of the seat lowered due to the body temperature of the seated person is reduced. Sex can be recovered quickly.
As a result, the seat air conditioning system can provide a new seat occupant with a comfortable seat that is not affected by the warmth or stuffiness of the previous seat occupant.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim shows the correspondence with the specific means as described in the embodiment described later.

It is a side view showing a schematic structure of a seat air-conditioner concerning a 1st embodiment. It is a block diagram which shows the control system of the seat air conditioner which concerns on 1st Embodiment. It is a flowchart regarding the control processing in the sheet | seat air conditioner which concerns on 1st Embodiment. It is explanatory drawing which shows an example of the control map used for determination of ventilation volume. It is a side view which shows an example of the driving | running content at the time of a passenger | crew leaving in 1st Embodiment. It is a side view which shows schematic structure of the seat air conditioning system which concerns on 2nd Embodiment. It is a block diagram which shows the control system of the seat air conditioning system which concerns on 2nd Embodiment. It is a flowchart regarding the control processing in the seat air-conditioning system concerning a 2nd embodiment. It is a side view which shows an example of the driving | running content at the time of a passenger | crew leaving in 2nd Embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings. Further, in the embodiment, when only a part of the constituent elements are described, the constituent elements described in the preceding embodiment can be applied to the other parts of the constituent elements.

  In the following embodiments, the embodiments can be partially combined with each other even if they are not clearly shown, as long as they do not particularly hinder the combination.

(First embodiment)
First, a first embodiment of the present invention will be described with reference to FIGS. The seat air-conditioning apparatus 1 according to the first embodiment is applied to a seat 30 disposed in a vehicle cabin. The seat air conditioner 1 is configured to operate according to the operation of the control unit 50, and improves the comfort by setting the range where the occupant P seated on the seat 30 is positioned as the air-conditioning target space.

  First, the configuration of the seat 30 on which the seat air conditioner 1 is arranged will be described. As shown in FIG. 1, the seat 30 has a seat surface portion 31 and a backrest portion 32, and is arranged so as to be slidable in the front-rear direction of the vehicle with respect to the floor surface of the passenger compartment.

  The seat surface portion 31 is a portion on which the occupant P is seated, and has a lower cushion portion 31A formed of a porous cushion on the upper surface side thereof. The lower cushion portion 31 </ b> A functions as a cushioning material when the occupant P is contacted and supported from below, and ensures air permeability to the upper surface side of the seat surface portion 31. The lower cushion portion 31 </ b> A constitutes a seat surface portion in the seat surface portion 31.

  And the backrest part 32 comprises the part which supports the passenger | crew P who sat on the seat surface part 31 from back, and has the upper side cushion part 32A made from porous on the front side. The upper cushion portion 32 </ b> A functions as a cushioning material when the occupant P is brought into contact with and supported from behind, and ensures air permeability to the front side of the backrest portion 32. The upper cushion portion 32 </ b> A constitutes a seat surface portion in the backrest portion 32.

  Here, when an occupant P as a seated person sits on the seat 30, the lower half of the occupant P comes into contact with the upper surface of the seat surface portion 31 as shown in FIG. 1. For this reason, between the upper surface of the seat surface part 31 and the lower body of the passenger | crew P, the retention part R which warms by the body temperature of the passenger | crew P and in which the steam | steamed air by action, such as sweating, tends to arise.

  When the occupant P is seated, the upper body of the occupant P comes into contact with the front surface of the backrest portion 32. Thereby, between the front surface of the backrest part 32 and the upper half of the passenger | crew P, the retention part R tends to arise like the seat surface part 31 side. In addition, each staying part R shown in FIG. 1 etc. is typical, and the range etc. are not shown strictly.

  The steamed air heated by the body temperature of the occupant P stays in the stay part R for a certain period even after the occupant P leaves the seat. For this reason, when a new occupant P is seated on the seat 30, the new occupant P may feel the warmth or stuffiness of the occupant P who has left the seat, and may feel uncomfortable.

  As shown in FIG. 1, the seat air conditioner 1 according to the first embodiment is disposed inside the seat surface portion 31 and the backrest portion 32 of the seat 30, and includes the lower ventilation path 10, the first blower 15, An upper ventilation path 20 and a second blower 25 are provided.

  The lower air passage 10 is disposed below the lower cushion portion 31A in the seat surface portion 31 of the seat 30, and is configured by combining metal pipes. The lower ventilation path 10 functions as an aggregate part in the seat surface part 31 of the seat 30.

  And the said lower side ventilation path 10 functions as an air flow path in the seat surface part 31 side of the seat air conditioner 1, the ventilation hole connected to the downward space between the seat surface part 31 and a floor surface, and the seat surface part 31 A plurality of ventilation holes arranged on the upper surface (that is, the lower cushion portion 31A) side are connected. The lower ventilation path 10 functions as a part of the ventilation path.

  In the first embodiment, the vent that communicates with the lower space of the seat portion 31 constitutes the lower suction port 11. On the other hand, the plurality of vent holes arranged on the upper surface side of the seat surface portion 31 constitute a plurality of lower air outlets 12.

  The lower suction port 11 is disposed at an end portion of the lower ventilation passage 10 and communicates with a lower space between the lower surface of the seat surface portion 31 and the floor surface. On the other hand, the plurality of lower air outlets 12 are disposed at a plurality of locations on the upper surface of the seat surface portion 31 and communicate with the inside of the hollow lower air passage 10.

  Therefore, in the first embodiment, the space below the seat surface portion 31 is located above the seat surface portion 31 (that is, when the seated passenger P is seated) via the lower cushion portion 31A and the lower air passage 10 of the seat surface portion 31. Existing space).

  And the 1st air blower 15 is arrange | positioned on the air flow path by the lower side ventilation path 10 inside the seat surface part 31. As shown in FIG. That is, the 1st air blower 15 which concerns on 1st Embodiment is arrange | positioned between the lower inlet 11 in the lower ventilation path 10, and the several lower air outlet 12. FIG. The said 1st air blower 15 is comprised so that air blowing operation may be performed with the control signal from the control part 50, and can control the ventilation volume by controlling operation | movement of the motor etc. which are not shown in figure.

  Therefore, the 1st air blower 15 can suck | inhale air from the lower inlet 11 in the lower ventilation path 10, and can blow off air from the several lower air outlet 12 by controlling the action | operation. The first blower 15 functions as one of the blowers.

  That is, the seat air-conditioning apparatus 1 according to the first embodiment sucks the air below the seat surface portion 31 into the lower ventilation path 10 and passes the lower cushion portion 31A of the seat surface portion 31 above the seat surface portion 31. Can be blown into the air.

  And the upper side ventilation path 20 is arrange | positioned inside the backrest part 32 behind the upper side cushion part 32A of the backrest part 32, and is comprised combining the metal pipe similarly to the lower side ventilation path 10. As shown in FIG. . Accordingly, the upper ventilation path 20 functions as an aggregate part in the backrest part 32 of the seat 30.

  And the said upper side ventilation path 20 functions as an air flow path in the backrest part 32 side of the sheet | seat air conditioner 1, the ventilation hole connected to the space of the back side of the backrest part 32, and the front surface (namely, backrest part 32). A plurality of vent holes arranged on the upper cushion part 32A) side are connected. The upper ventilation path 20 functions as a part of the ventilation path.

  In the first embodiment, the vent that communicates with the space on the back side of the backrest portion 32 constitutes the upper suction port 21. On the other hand, the plurality of vents arranged on the front side of the backrest portion 32 constitute a plurality of upper air outlets 22.

  The upper suction port 21 is formed at an end portion of the upper ventilation path 20 and communicates with a space on the back side of the backrest portion 32. The plurality of upper air outlets 22 are disposed at a plurality of locations on the front surface of the backrest portion 32 and communicated with the inside of the hollow upper ventilation path 20.

  Therefore, in the first embodiment, the space behind the backrest portion 32 is the front of the backrest portion 32 (that is, the space where the seated occupant P is present) via the cushion portion of the backrest portion 32 and the upper ventilation path 20. Communicate.

  The second blower 25 is disposed on the air flow path formed by the upper ventilation path 20 inside the backrest portion 32. That is, the second blower 25 is disposed between the upper suction port 21 in the upper ventilation path 20 and the plurality of upper blowout ports 22. The second blower 25 is configured to perform a blowing operation according to a control signal from the control unit 50, and can control the amount of blown air by controlling the operation of a motor or the like (not shown).

  Therefore, by controlling the operation of the second blower 25, the second blower 25 can suck air from the upper suction port 21 in the upper ventilation path 20 and blow out air from the plurality of upper blowout ports 22. The second blower 25 functions as one of the blowers.

  The seat air-conditioning apparatus 1 according to the first embodiment sucks the air on the back side of the backrest portion 32 into the upper ventilation path 20 and enters the space on the front side of the backrest portion 32 via the upper cushion portion 32A of the backrest 32. Can blow.

  In other words, the seat air conditioner 1 according to the first embodiment sucks in the air in the passenger compartment below and on the rear side of the seat air conditioner 1 and is a seated person via the lower cushion portion 31A and the upper cushion portion 32A. It is possible to perform a blowing operation with the position of the occupant as the air conditioning target range.

  The seat air conditioner 1 is supplied with power from the in-vehicle battery, and the power line from the in-vehicle battery is configured with a coil wiring having a margin so as to allow the seat 30 to slide.

  The seat air conditioner 1 configured as described above operates according to the control by the control unit 50, so that the air in the passenger compartment can be taken into the seat surface portion 31 and the backrest portion 32 of the seat 30. The comfort of the seated occupant can be improved.

  Next, the control system of the seat air conditioner 1 according to the first embodiment will be described in detail with reference to the drawings. As shown in FIG. 2, the control unit 50 is a control unit that controls the operation of each control target device constituting the seat air conditioning system 100, and functions as a control unit. The control unit 50 includes a known microcomputer including a CPU, a ROM, a RAM, and the like and peripheral circuits thereof.

  And the control part 50 which concerns on 1st Embodiment has memorize | stored the control program for performing the air-conditioning operation | movement of the sheet | seat air conditioner 1 in the ROM, and performs various arithmetic processing based on the control program. The control program shown in FIG. 3 is also stored in the ROM of the control device 60.

  As shown in FIG. 2, various detection units are connected to the input side of the control unit 50. The various detection units include a seating sensor 51, a surface temperature sensor 52, a surface humidity sensor 53, an indoor temperature sensor 54, and an indoor humidity sensor 55.

  The seating sensor 51 is a detection unit for detecting whether the passenger P is seated on the seat 30. The seating sensor 51 is configured by a weight sensor disposed on the seat surface portion 31 of the seat 30. When the weight of the occupant P is detected, a detection signal indicating that the occupant P is seated on the seat 30 is provided. Output. The seating sensor 51 functions as a seating detection unit.

  The surface temperature sensor 52 is disposed in the lower cushion portion 31A and the upper cushion portion 32A of the seat 30, and detects the temperatures of the lower cushion portion 31A and the upper cushion portion 32A as the surface temperature Ts. The surface temperature Ts is used as an index indicating an increase in the temperature of the surface of the seat 30 due to the body temperature of the occupant P seated on the seat 30.

  The surface humidity sensor 53 is disposed in the lower cushion portion 31A and the upper cushion portion 32A of the seat 30, and detects the humidity of the lower cushion portion 31A and the upper cushion portion 32A as the surface humidity Hs. The surface humidity Hs is used as an index indicating an increase in humidity on the surface of the seat 30 due to sweating or the like of the occupant P seated on the seat 30.

  The room temperature sensor 54 is a detection unit that detects the temperature in the vehicle compartment in which the seat 30 is disposed as the room temperature Tr. The room temperature Tr is used as an index indicating the temperature environment around the seat 30 and corresponds to the ambient temperature.

  The indoor humidity sensor 55 is a detection unit that detects the humidity in the vehicle compartment in which the seat 30 is disposed as the indoor humidity Hr. The indoor humidity Hr is used as an index indicating the humidity environment around the seat 30 and corresponds to the atmospheric humidity.

  And the control object apparatus in the seat air conditioner 1 is connected to the output side of the said control part 50. FIG. Specifically, the control target device includes a first blower 15 and a second blower 25. Therefore, the said control part 50 can each be adjusted to arbitrary ventilation volume by controlling the control voltage input into the 1st air blower 15 and the 2nd air blower 25. FIG.

  In addition, in the said control part 50, although the control part which controls the various control object apparatus connected to the output side is comprised integrally, the structure (hardware and software) which controls the operation | movement of each control object apparatus. However, the control part which controls the action | operation of each control object apparatus is comprised.

  For example, the configuration of determining whether or not the occupant P has left the seat 30 based on a change in the detection signal from the seating sensor 51 in the control unit 50 is the absence determination unit 50A. And the structure which controls the action | operation of the 1st air blower 15 and the 2nd air blower 25 according to the control program shown in FIG. 3 among the control parts 50 is the air flow control part 50B.

  Further, regarding the occupant P who has left the seat 30 in the control unit 50, the seating situation when the occupant P is seated on the seat 30 is identified and identified based on the detection result of the surface temperature sensor 52 or the like. The configuration for determining whether or not the seated situation satisfies the predetermined criteria satisfies the seating status determination unit 50C.

  Then, the content of the control processing of the sheet | seat air conditioner 1 which concerns on 1st Embodiment is demonstrated, referring FIGS. 3-5. The control program shown in the flowchart in FIG. 3 is executed by the CPU of the control unit 50 when the seat air conditioner 1 is activated.

  As shown in FIG. 3, in step S <b> 1, it is determined whether or not the occupant P is seated on the seat 30. The determination process in step S <b> 1 is executed based on a detection signal from the seating sensor 51. That is, when the weight of the occupant P is detected by the seating sensor 51, it is determined that the occupant P is seated on the seat 30.

  When it is determined that the occupant P is seated on the seat 30, the process proceeds to step S2. On the other hand, if not, the control program according to the first embodiment is terminated as it is. The control program is periodically executed at predetermined intervals.

  In step S2, it is determined whether or not the occupant P seated in step S1 has left. The determination process of step S2 is executed based on whether or not the detection signal of the seating sensor 51 has changed from a detection signal that has detected the weight of the occupant P to a signal that indicates that no weight has been detected.

  When it is determined that the seated passenger P has left the seat 30, the process proceeds to step S3. On the other hand, if this is not the case, the passenger P remains seated on the seat 30 and waits for processing. The control unit 50 when executing step S2 functions as an absence determination unit 50A.

  In step S3, with respect to the occupant P who has left the seat in step S2, it is determined whether or not the seating status of the occupant P satisfies the reference condition. Here, the seating status indicates the status of the staying portion R that changes with the seating of the occupant P. In the first embodiment, as an index indicating the seating status, the surface temperature Ts when the occupant P leaves the seat. Is adopted.

  The reference condition is a condition that means that it is necessary to clear the steamed air in the staying portion R, and is warmed to some extent by the body temperature of the occupant P who has left the seat. It shows a state where comfort is lowered.

  As the reference condition according to the first embodiment, it is adopted that the surface temperature Ts is higher than a predetermined reference surface temperature KTs. The reference surface temperature KTs is set to, for example, a surface temperature Ts at which a newly seated passenger P feels uncomfortable.

  If the surface temperature Ts detected by the surface temperature sensor 52 is higher than the reference surface temperature KTs, the process proceeds to step S4 because the reference condition is satisfied. That is, the case of shifting to step S4 means a state in which the comfort of the seat 30 is lowered due to the body temperature of the occupant P who has left the seat. On the other hand, if not, the control program shown in FIG. The control unit 50 when executing step S3 functions as a seating state determination unit 50C.

  In step S4, the air flow rate Q of the 1st air blower 15 and the 2nd air blower 25 for recovering the comfort of the seat | sheet 30 which fell by the body temperature etc. of the passenger | crew P who left the seat is determined. In 1st Embodiment, the ventilation volume Q of the 1st air blower 15 and the 2nd air blower 25 refers to the surface temperature Ts when the passenger | crew P leaves | separated and the control map memorize | stored in ROM of the control apparatus 60. FIG. It is determined.

  Here, the control map referred to in step S4 according to the first embodiment will be described with reference to FIG. As described above, in step S4, the air flow rate Q of the first blower 15 and the second blower 25 is determined according to the surface temperature Ts.

  As shown in FIG. 4, the control map is configured by associating the air flow rate Q with the surface temperature Ts. Specifically, the minimum air flow rate Qa is associated with the reference surface temperature KTs as the air flow rate Q of the first blower 15 and the second blower 25.

  In the control map, as the surface temperature Ts becomes higher than the reference surface temperature KTs, the air flow rate Q of the first blower 15 and the second blower 25 is associated with the air flow rate larger than the minimum air flow rate Qa. Yes.

  Here, the surface temperature Ts and the surface humidity Hs tend to indicate higher values as the passenger P sits on the seat 30 for a longer period of time. For this reason, when waiting for the warmth and stuffiness caused by the body temperature of the occupant P to be eliminated naturally, the higher the numerical value such as the surface temperature Ts, the longer the period is required.

  As in the case of the seat air conditioner 1, even when the steamed air in the staying part R is ventilated by blowing by the first blower 15 and the second blower 25, if it is operated with a predetermined blowing amount, The longer the surface temperature Ts and the surface humidity Hs, the longer the period is required.

  In this regard, in step S4, according to the control map shown in FIG. 4, the air flow rate Q of the first blower 15 and the second blower 25 is larger than the minimum air flow rate Qa as the surface temperature Ts becomes higher than the reference surface temperature KTs. It is determined to be.

  For this reason, even if the surface temperature Ts and the surface humidity Hs are high, the seat air conditioner 1 can ventilate the steamed air in the staying portion R with a large air flow rate. As a result, the seat air conditioner 1 quickly recovers the comfort of the seat 30 that has decreased due to the body temperature or sweating of the occupant P even when the occupant P has been seated for a long time. be able to.

  The processing after step S5 will be described with reference to FIG. 3 again. When the air flow rate Q is determined in step S4 and the process proceeds to step S5, the operation of the first blower 15 and the second blower 25 is executed according to the operation control of the control device 60. At this time, the air flow rate Q of the first blower 15 and the second blower 25 is controlled to be the numerical value determined in step S4.

  As shown in FIG. 5, in the seat surface portion 31 of the seat 30, the first blower 15 sucks air between the seat surface portion 31 and the floor surface via the lower suction port 11. And the said 1st air blower 15 blows off air from the several lower side blower outlet 12, and supplies it above the seat surface part 31 via lower side cushion part 31A.

  Thereby, the steamed air staying on the surface of the lower cushion portion 31 </ b> A in the seat surface portion 31 flows out of the lower cushion portion 31 </ b> A due to the flow of the blown air A blown from the first blower 15. That is, the seat air conditioner 1 can lower the surface temperature Ts and the surface humidity Hs in the seat surface portion 31 by blowing air from the first blower 15.

  At the same time, at the seat back portion 32, the second blower 25 sucks the empty space on the back side of the seat 30 through the upper suction port 21. And the said 2nd air blower 25 blows off air from the some upper side blower outlet 22, and supplies it ahead of the backrest part 32 via 32 A of upper side cushion parts.

  Thereby, the steamed air staying on the surface of the upper cushion portion 32A in the backrest portion 32 flows out of the upper cushion portion 32A by the flow of the blown air A blown from the second blower 25. That is, the seat air conditioner 1 can lower the surface temperature Ts and the surface humidity Hs in the backrest portion 32 by blowing air from the second blower 25.

  That is, according to the seat air conditioner 1, the comfort of the seat 30, which has been lowered due to the body temperature of the occupant P who is seated or sweating, is quickly recovered by the air blow from the first blower 15 and the second blower 25. Therefore, a comfortable seat 30 can be provided for the passenger P who is seated thereafter. The control part 50 at the time of performing step S4-step S5 mentioned above is corresponded to the ventilation control part 50B.

  After starting the operation of the first blower 15 and the second blower 25, in step S6, it is determined whether or not an operation stop condition for stopping the operation of the first blower 15 and the like is satisfied. The operation stop condition in the first embodiment is that the surface temperature Ts detected by the surface temperature sensor 52 is lower than the operation stop temperature ST.

  The operation stop temperature ST in this case is determined according to the indoor temperature Tr detected by the indoor temperature sensor 54, and is, for example, a temperature that is 1 ° C. lower than the indoor temperature Tr. The operation stop temperature ST may be the same temperature as the room temperature Tr, or may be a temperature having a level difference of several degrees Celsius based on the room temperature Tr.

  When the operation stop condition is satisfied, the surface temperature Ts and the like of the seat surface portion 31 and the backrest portion 32 are sufficiently lowered, and the comfort of the seat 30 is restored. On the other hand, when that is not right, a process is returned to step S5 and the ventilation by the 1st air blower 15 and the 2nd air blower 25 is continued.

  In step S7, the operation of the first blower 15 and the second blower 25 is terminated when the operation stop condition is satisfied. At this time, the surface temperature Ts and the surface humidity Hs in the seat surface portion 31 and the backrest portion 32 are reduced to the same level as the room temperature Tr and the room humidity Hr. Therefore, even when the occupant P is newly seated, the person leaves the seat. Sufficient comfort can be ensured without the passenger P feeling warm or damp.

  As shown in FIGS. 3 to 5, according to the seat air conditioner 1, when the occupant P leaves the seat 30, the air blown by the first blower 15 and the second blower 25 is changed to the lower cushion. The air is blown through the portion 31A and the upper cushion portion 32A.

  Thereby, the said seat air conditioner 1 can discharge the warmth and stuffiness resulting from the body temperature of the occupant P who has left the seat from the surface of the seat 30 as early as possible from the time when the occupant P has left the seat. Therefore, even when a new occupant P is seated immediately after the occupant P leaves the seat 30, it is possible to prevent the user from feeling uncomfortable due to warmth or the like.

  As described above, the seat air-conditioning apparatus 1 according to the first embodiment is applied to the seat 30 configured to allow the passenger P to be seated. As shown in FIG. 1, when the occupant P is seated on the seat 30, the lower cushion portion 31 </ b> A and the upper cushion portion 32 </ b> A may be warmed and steamed due to the occupant P's body temperature, sweating, and the like. is assumed.

  According to the seat air conditioner 1 according to the first embodiment, when it is determined in step S2 that the occupant P has left the seat 30, the first blower 15 and the second blower 25 are operated, Air blowing is performed via the side cushion portion 31A and the upper cushion portion 32A. Thereby, the said seat air conditioner 1 can exclude from the lower cushion part 31A and the upper cushion part 32A the steamed air warmed by the body temperature and sweating of the occupant P who has left the seat.

  That is, according to the seat air conditioner 1, when the occupant P leaves the seat 30, the first air blower 15 and the second air blower 25 blow the air, and the seat 30 is lowered due to the body temperature of the occupant P. Comfort can be restored. As a result, the seat air conditioner 1 can provide a comfortable seat 30 that is not affected by the warmth or stuffiness of the previous occupant P with respect to the new occupant P.

  The seat air-conditioning apparatus 1 according to the first embodiment blows air from the first blower 15 and the second blower 25 when it is determined in step S3 that the seating situation regarding the occupant P who has left the seat satisfies the standard condition. Do. This reference condition means the situation of the staying portion R that changes as the occupant P is seated, and indicates that the comfort of the seat 30 is lower than a predetermined reference by the occupant P who has left the seat.

  Therefore, the seat air conditioner 1 determines the degree of comfort reduction of the seat 30 by the occupant P who has left the seat, and when the necessity is high, the comfort of the seat 30 is recovered by blowing air from the first blower 15 or the like. Can be made.

  The reference condition in step S3 of the first embodiment is that the surface temperature Ts is higher than the reference surface temperature KTs. In the seat 30, the surface temperature Ts detected by the surface temperature sensor 52 increases as the time for the passenger P to sit is longer. The surface temperature Ts of the seat 30 corresponds to the warmth felt by the occupant P seated on the seat 30.

  That is, according to the seat air-conditioning apparatus 1 according to the first embodiment, the degree of comfort reduction of the seat 30 by the occupant P who has left the seat is accurately determined from the viewpoint of the warmth felt by the newly occupant P. Can do. Thereby, the said seat air conditioner 1 can perform ventilation operation | movement of the 1st air blower 15 grade | etc., At an appropriate timing regarding the fall degree of the comfort of the seat 30, and can restore the comfort of the seat 30. .

  As shown in FIG. 3, in step S <b> 4, the seat air conditioner 1 refers to the control map, and the air flow rate Q of the first blower 15 and the second blower 25 increases as the surface temperature Ts of the seat 30 increases. To be determined.

  From the viewpoint of warmth felt by the newly seated passenger P, it can be said that the higher the surface temperature Ts, the more the comfort in the seat 30 is reduced. According to the seat air conditioner 1, the comfort of the seat 30 that has been greatly reduced can be recovered as early as possible by increasing the air flow rate Q of the first blower 15 and the like as the surface temperature Ts increases.

  According to the seat air conditioner 1 according to the first embodiment, when the operation stop condition is satisfied in step S6, the air blowing operation of the first blower 15 and the second blower 25 is ended. The operation stop condition in step S6 is that the surface temperature Ts is lower than the operation stop temperature ST determined based on the room temperature Tr. In this situation, even if a new occupant P is seated on the seat 30, the seated occupant P does not feel the warmth of another person (for example, the occupant P who has left the seat).

  That is, the seat air-conditioning apparatus 1 ends the air blowing operation of the first blower 15 and the like when the lowered comfort of the seat 30 is sufficiently recovered, and therefore, it is useless regarding the recovery of the comfort of the seat 30. The air blowing operation can be prevented. In other words, the seat air conditioner 1 can save energy with respect to the restoration of the comfort of the seat 30.

(First modification according to the first embodiment)
Here, a first modification will be described as a modification according to the first embodiment described above. In the said 1st modification, the content of the reference | standard conditions in step S3 of FIG. 3 is different, and the fundamental structure and control content which concern on the other sheet | seat air conditioner 1 are comprised similarly to 1st Embodiment. Yes.

  Specifically, in the seat air conditioner 1 according to the first modified example, it is adopted that the surface humidity Hs detected by the surface humidity sensor 53 is higher than the reference surface humidity KHs as the reference condition in step S3. Similarly to FIG. 3, when the surface humidity Hs is higher than the reference surface humidity KHs, the process proceeds to step S4, and otherwise, the control program according to the first modification is terminated.

  According to the seat air-conditioning apparatus 1 according to the first modified example, the effects obtained from the configuration and operation common to the above-described first embodiment can be obtained similarly to the first embodiment.

  By setting the reference condition as in step S3 in the first modification, the seat air conditioner 1 can comfort the seat 30 due to sweating of the occupant P who has left the seat in terms of the degree of stuffiness felt by the occupant P who is newly seated. Can be determined.

(Second modification according to the first embodiment)
Next, a second modification will be described as a modification according to the first embodiment described above. In the second modified example, the content of the reference condition in step S3 in FIG. 3 is different, and the basic configuration and control content related to the other seat air conditioners 1 are configured in the same manner as in the first embodiment. Yes.

  Specifically, in the seat air-conditioning apparatus 1 according to the second modification, as a reference condition in step S3, the seating time t of the passenger P who left the seat in step S2 is longer than a predetermined reference seating time Kt. Is adopted. As in FIG. 3, when the seating time t is longer than the reference seating time Kt, the process proceeds to step S4, and when not, the control program according to the second modification is terminated.

  The seating time t means the time from when the occupant P is detected by the seating sensor 51 in step S1 to when the occupant P leaves the seat in step S2, and the number of clocks of the CPU of the control unit 50 Is detected based on In addition, you may use the timer for time measurement separately for the measurement of the seating time t.

  According to the seat air-conditioning apparatus 1 according to the second modified example, it is possible to obtain the effects obtained from the configuration and operation common to the above-described first embodiment as in the first embodiment.

  Here, as the seating time t of the occupant P with respect to the seat 30 is longer, the lower cushion portion 31A and the upper cushion portion 32A are affected by the body temperature and sweating of the occupant P, so the surface temperature Ts and the surface humidity Hs are higher. Show the trend. Accordingly, it is possible to estimate the surface temperature Ts and the surface humidity Hs based on the seating time t.

  In other words, by setting the reference condition as in step S3 in the second modification, the seat air conditioner 1 allows the occupant to leave the seat without specially arranging the detection units such as the surface temperature sensor 52 and the surface humidity sensor 53. The degree of decrease in comfort of the seat 30 due to P can be determined.

(Third Modification Example According to First Embodiment)
Subsequently, a third modification will be described as a modification according to the first embodiment described above. In the 3rd modification, the contents of processing in Step S4 of Drawing 3, and the contents of a control map differ, and the fundamental composition and control contents concerning other seat air-conditioning devices 1 are the same as that of a 1st embodiment. is there.

  Specifically, in the seat air conditioner 1 according to the third modification, the first blower 15 and the second blower 15 are controlled based on the surface humidity Hs detected by the surface humidity sensor 53 and the control map in step S4. The air flow rate Q of the blower 25 is determined.

  In the control map in this case, as in the example shown in FIG. 4, as the surface humidity Hs becomes higher than the reference surface humidity KHs, the air flow rate Q of the first blower 15 and the second blower 25 is greater than the minimum air flow rate Qa. Corresponding to be larger.

  According to the seat air-conditioning apparatus 1 according to the first modified example, the effects obtained from the configuration and operation common to the above-described first embodiment can be obtained similarly to the first embodiment.

  By determining as in step S4 and the control map in the third modification, the seat air conditioner 1 allows the air volume Q of the first blower 15 and the second blower 25 from the viewpoint of the degree of suffocation felt by the newly seated passenger P. Can be determined, and the comfort of the seat 30 can be recovered early.

(Fourth modified example according to the first embodiment)
And a 4th modification is demonstrated as a modification which concerns on 1st Embodiment mentioned above. In the 4th modification, the contents of processing in Step S4 of Drawing 3, and the contents of a control map differ, and the fundamental composition and control contents concerning other seat air conditioners 1 are the same as that of a 1st embodiment. is there.

  Specifically, in the seat air conditioner 1 according to the fourth modification, the first blower 15 and the second blower 25 are based on the seating time t related to the occupant P who has left the seat and the control map in step S4. Is determined.

  As in the example shown in FIG. 4, the control map in this case is associated so that the air flow rate Q of the first blower 15 and the second blower 25 increases as the seating time t increases.

  According to the seat air-conditioning apparatus 1 according to the first modified example, the effects obtained from the configuration and operation common to the above-described first embodiment can be obtained similarly to the first embodiment.

  By determining as in step S4 and the control map in the fourth modification, the seat air conditioner 1 allows the first blower 15 and the second blower 25 to be used without using sensors such as the surface temperature sensor 52 and the surface humidity sensor 53. The air flow rate Q can be determined, and the comfort of the seat 30 can be recovered early.

(Fifth Modification Example According to First Embodiment)
Next, a fifth modification will be described as a modification according to the first embodiment described above. In the fifth modified example, the operation stop conditions in step S6 of FIG. 3 are different, and the basic configuration and control contents related to other seat air conditioners 1 are the same as those in the first embodiment.

  More specifically, in the seat air conditioner 1 according to the fifth modification, the operation stop in which the surface humidity Hs detected by the surface humidity sensor 53 is set based on the indoor humidity Hr as the operation stop condition in step S6. It is adopted that the humidity is lower than SH. If the surface humidity Hs is lower than the operation stop humidity SH, the process proceeds to step S7, and if not, the process returns to step S5.

  According to the seat air-conditioning apparatus 1 according to the fifth modified example, the effects obtained from the configuration and operation common to the above-described first embodiment can be obtained similarly to the first embodiment.

  By setting the operation stop condition as in step S6 in the fifth modification, the seat air conditioner 1 restores comfort by blowing air from the first blower 15 and the like from the viewpoint of the degree of suffocation felt by the newly seated passenger P The degree can be determined, and a comfortable seat 30 without stuffiness can be provided.

  In addition, it is also possible to comprise so that the ventilation operation of the 1st air blower 15 and the 2nd air blower 25 may be complete | finished as progress of the predetermined | prescribed operation period as an operation stop condition in step S6.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIGS. The seat air conditioning system 100 according to the second embodiment is mounted on a vehicle and is used to adjust the interior of the vehicle compartment C of the vehicle to an appropriate temperature.

  As shown in FIGS. 6 and 7, the seat air-conditioning system 100 according to the second embodiment is mainly air-conditioned in the passenger compartment C with respect to the seat air-conditioning apparatus 1 configured in the same manner as the first embodiment described above. The vehicle air conditioner 40 that performs the above and the control device 60 that controls the operation of the seat air conditioner 1 and the vehicle air conditioner 40 are added.

  Therefore, since the common configuration related to the seat air conditioner 1 and the seat 30 is the same as that of the first embodiment described above, the description thereof is omitted, and differences from the first embodiment will be described.

  The seat air conditioner 1 according to the second embodiment is basically configured similarly to the first embodiment, but the operation modes of the first blower 15 and the second blower 25 are different from those of the first embodiment. . In the following description, differences from the first embodiment will be described.

  Specifically, the first blower 15 according to the second embodiment sucks air through the lower cushion portion 31 </ b> A and exhausts the air that has passed through the lower ventilation path 10 to the lower portion of the seat surface portion 31. It is configured.

  For this reason, the lower suction port 11 which concerns on 2nd Embodiment is comprised by the several ventilation port arrange | positioned by the side of the lower cushion part 31A in the seat surface part 31 contrary to 1st Embodiment. Similarly, the lower air outlet 12 according to the second embodiment is configured by a vent arranged below the seat surface portion 31.

  Further, the second blower 25 according to the second embodiment sucks air through the upper cushion portion 32A and exhausts the air that has passed through the upper ventilation passage 20 to the back side of the backrest portion 32 (that is, the vehicle rear side). It is configured as follows.

  For this reason, the upper suction port 21 according to the second embodiment includes a plurality of ventilation holes arranged on the upper cushion portion 32A side in the backrest portion 32, contrary to the first embodiment. Similarly, the upper air outlet 22 according to the second embodiment is configured by a vent arranged on the back side of the backrest portion 32.

  Next, the configuration of the vehicle air conditioner 40 according to the second embodiment will be described in detail with reference to the drawings. As shown in FIGS. 1 and 2, the vehicle air conditioner 40 is disposed inside the foremost instrument panel (for example, an instrument panel) in the passenger compartment C, and is adjusted by the refrigeration cycle apparatus 43. The CA can be supplied into the passenger compartment C. The vehicle air conditioner 40 functions as a vehicle air conditioner constituting the seat air conditioning system 100.

  The vehicle air conditioner 40 includes an indoor blower 42, an evaporator 44 constituting a refrigeration cycle apparatus 43, and the like inside a casing 41 that forms an outer shell thereof. The vehicle air conditioner 40 can realize operation modes such as a heating mode, a cooling mode, and a dehumidifying heating mode by switching the refrigerant circuit and the like of the refrigeration cycle apparatus 43.

  The casing 41 forms an air passage for blown air blown into the passenger compartment C. The casing 41 is formed of a resin (for example, polypropylene) having a certain elasticity and excellent in strength.

  And although illustration is abbreviate | omitted in the inside of the said casing 41, the inside / outside air switching box, a heater core, a bypass channel, an air mix door, etc. are accommodated. The inside / outside air switching box simultaneously introduces inside air and outside air at the most upstream part of the air passage of the casing 41, and an inside air mode for introducing inside air (vehicle compartment air), an outside air mode for introducing outside air (vehicle compartment outside air), and inside air and outside air. It is configured to be able to switch between semi-inside air modes.

  An electric indoor blower 42 is disposed downstream of the inside / outside air switching box. The indoor blower 42 is configured to drive a multiblade fan by a motor and blow air into the passenger compartment C. The indoor blower 42 can adjust the amount of air blown into the passenger compartment C by the indoor blower 42 by performing drive control of the motor by the control device 60.

  As shown in FIG. 6, an evaporator 44 constituting the refrigeration cycle apparatus 43 is disposed on the downstream side of the indoor blower 42. Here, the refrigeration cycle apparatus 43 of the vehicle air conditioner 40 is configured as a vapor compression refrigeration cycle, and includes a compressor, a condenser, and an expansion valve in addition to the evaporator 44.

  In the refrigeration cycle apparatus 43, the compressor sucks, compresses and discharges the refrigerant of the refrigeration cycle apparatus 43. The condenser causes heat exchange between the high-pressure refrigerant discharged from the compressor and the air outside the vehicle (that is, outside air) blown from the outdoor blower to condense the refrigerant. The condenser functions as a so-called radiator.

  The expansion valve is a decompression unit that decompresses and expands the liquid-phase refrigerant that has flowed out of the condenser. The expansion valve includes a valve body and an electric actuator and includes an electric variable throttle mechanism. In the refrigeration cycle apparatus 43, when the low-pressure refrigerant decompressed by the expansion valve flows into the evaporator 44, it absorbs heat from the blown air blown by the indoor blower 42 and evaporates. Therefore, the evaporator 44 can cool and dehumidify the blown air blown from the indoor blower 42.

  In the refrigeration cycle apparatus 43, the refrigerant that has flowed into the evaporator 44 and evaporated then flows into the compressor again. Thus, a refrigeration cycle in which refrigerant circulates in the order of compressor → condenser → expansion valve → evaporator 44 → compressor is configured. The above-described refrigeration cycle components (evaporator 44, compressor to expansion valve) are connected by refrigerant piping.

  The refrigeration cycle apparatus 43 employs an HFC-based refrigerant (specifically, R134a) as the refrigerant, and constitutes a vapor compression subcritical refrigeration cycle in which the high-pressure side refrigerant pressure does not exceed the critical pressure of the refrigerant. Has been.

  Of course, an HFO refrigerant (for example, R1234yf), a natural refrigerant (for example, R744), or the like may be employed as the refrigerant. Furthermore, refrigeration oil for lubricating the compressor is mixed in the refrigerant, and a part of the refrigeration oil circulates in the cycle together with the refrigerant.

  And the heater core is arrange | positioned in the air flow downstream of the evaporator 44 in the air conditioner 40 for vehicles. The heater core heats the air (cold air) that has passed through the evaporator 44 using, as a heat source, vehicle engine coolant that circulates through an engine coolant circuit (not shown).

  A bypass passage is formed on the side of the heater core. The bypass passage guides the air that has passed through the evaporator 44 to the downstream side of the air flow of the heater core, bypassing the heater core.

  Further, a defroster outlet, a face outlet 45, and a foot outlet are arranged at the most downstream portion of the blown air flow of the casing 41. These air outlets are formed so as to blow out the conditioned air CA, the temperature of which is adjusted by an air mix door (not shown), into the cabin C, which is the air-conditioning target space.

  As shown in FIG. 6, the face outlet 45 is formed in an instrument panel (for example, an instrument panel) in the front part of the passenger compartment C, and blows the conditioned air CA to the upper body of the passenger P seated on the seat 30. This is the outlet.

  The vehicle air conditioner 40 configured as described above can operate in accordance with the control by the control device 60 to supply the conditioned air CA adjusted to an appropriate temperature into the passenger compartment C. Thereby, the said vehicle air conditioner 40 can improve the comfort of the passenger | crew P in the compartment C.

  Next, a control system in the seat air conditioning system 100 according to the second embodiment will be described with reference to FIG. As shown in FIG. 7, the control device 60 is a control device that controls the operation of each control target device constituting the seat air conditioning system 100 and operates the seat air conditioner 1 and the vehicle air conditioner 40 in a coordinated manner.

  The control device 60 includes a known microcomputer including a CPU, a ROM, a RAM, and the like and peripheral circuits thereof. The control device 60 stores a control program for performing an air conditioning operation in the passenger compartment by the seat air conditioning system 100 in the ROM, and performs various calculations and processes based on the control program. The control program shown in FIG. 8 is also stored in the ROM of the control device 60.

  As in the first embodiment, various detection units are connected to the input side of the control device 60. The various detection units include a seating sensor 51, a surface temperature sensor 52, a surface humidity sensor 53, an indoor temperature sensor 54, and an indoor humidity sensor 55. Since these seating sensors 51 to the indoor humidity sensor 55 have already been described in the first embodiment, description thereof will be omitted.

  The various detection units according to the second embodiment further include an air conditioning sensor group related to the vehicle air conditioner 40. The air conditioning sensor group includes an outside air sensor, an evaporator temperature sensor, a water temperature sensor, and the like.

  Various control target devices in the seat air conditioning system 100 are connected to the output side of the control device 60. As shown in FIG. 7, a first blower 15 and a second blower 25 are connected as control target devices related to the seat air conditioner 1.

  Moreover, the indoor air blower 42 and the refrigerating-cycle apparatus 43 are connected as control object apparatus regarding the vehicle air conditioner 40, for example. Therefore, the operation of the compressor, the expansion valve, the electromagnetic valve for switching the refrigerant circuit, etc. constituting the refrigeration cycle apparatus 43 is controlled by the control device 60.

  Therefore, the control device 60 in the seat air conditioning system 100 can execute the operation control for the seat air conditioning device 1 and the operation control for the vehicle air conditioning device 40, respectively.

  Note that the control device 60 according to the second embodiment controls the operation of each control target device constituting the vehicle air conditioner 40 and each control target device constituting the seat air conditioner 1. Although comprised, you may comprise so that it may have a control part with respect to the seat air conditioner 1, and a control part with respect to the vehicle air conditioner 40, respectively.

  In addition, in the said control apparatus 60, although the control part which controls the various control object apparatus connected to the output side is comprised integrally, the structure (hardware and software) which controls the action | operation of each control object apparatus. However, the control part which controls the action | operation of each control object apparatus is comprised.

For example, the configuration of the control device 60 that determines whether or not the occupant P has left the seat 30 based on a change in the detection signal from the seating sensor 51 is as follows.
The absence determination unit 60A. And the structure which controls the action | operation of the seat air conditioner 1 and the vehicle air conditioner 40 among the control apparatuses 60 according to the control program shown in FIG. 8 is the action control part 60B.

  Further, regarding the occupant P who has left the seat 30 in the control device 60, the seating situation when the occupant P is seated on the seat 30 is specified based on the detection result of the surface temperature sensor 52 or the like, The configuration for determining whether or not the specified seating condition satisfies a predetermined standard condition is the seating condition determination unit 60C.

  Then, the content of the control processing of the sheet | seat air conditioning system 100 which concerns on 2nd Embodiment is demonstrated, referring FIG. 8, FIG. The control program shown in the flowchart in FIG. 8 is executed by the CPU of the control device 60 when the seat air conditioning system 100 is activated.

  As shown in FIG. 8, in step S11, as in step S1 in the first embodiment, it is determined whether or not the seating of the occupant P on the seat 30 has been detected. When it is determined that the occupant P is seated on the seat 30, the process proceeds to step S12. On the other hand, if not, the control program according to the second embodiment is terminated as it is.

  In step S12, it is determined whether or not the occupant P seated in step S11 has left. The determination process of step S12 is the same process as step S2 according to the first embodiment.

  When it is determined that the occupant P who has been seated has left the seat 30, the process proceeds to step S13. On the other hand, if this is not the case, the passenger P remains seated on the seat 30 and waits for processing. The control device 60 when executing step S12 functions as the absence determination unit 60A.

  In step S13, regarding the occupant P who has left the seat in step S12, it is determined whether or not the seating condition of the occupant P satisfies the reference condition. As a reference condition in the second embodiment, as in step S3 of the first embodiment, it is adopted that the surface temperature Ts is higher than a predetermined reference surface temperature KTs.

  If the surface temperature Ts is higher than the reference surface temperature KTs, the process proceeds to step S14 because the reference condition is satisfied. On the other hand, if not, the control program shown in FIG. The control device 60 when executing step S13 functions as a seating state determination unit 60C.

  In addition, it is also possible to employ | adopt the conditions quoted by the 1st modification in 1st Embodiment, and the 2nd modification as reference conditions in step S13.

  If transfering it to step S14, the action | operation of the refrigerating-cycle apparatus 43 will be controlled by the control apparatus 60 so that the operation mode in the vehicle air conditioner 40 may turn into the air_conditioning | cooling mode. At the same time, the operation of the first blower 15 and the second blower 25 in the seat air conditioner 1 is controlled by the control device 60. The control device 60 when executing step S14 functions as an operation control unit 60B.

  Accordingly, as shown in FIG. 9, the conditioned air CA is blown out from the face air outlet 45 of the vehicle air conditioner 40 toward the seat 30. Since the vehicle air conditioner 40 is operated in the cooling mode, the conditioned air CA is cooled and dehumidified by heat exchange with the low-pressure refrigerant in the evaporator 44.

  And in the seat air conditioner 1 which concerns on 2nd Embodiment, if the driving | operation of the 1st air blower 15 is started, the 1st air blower 15 will use the air-conditioning wind CA supplied above the seat surface part 31 for lower cushion part 31A. Then, the air is sucked into the lower ventilation path 10 from the plurality of lower suction ports 11. The first blower 15 discharges the air sucked into the lower ventilation path 10 from the lower air outlet 12 between the seat surface portion 31 and the floor surface.

  Thereby, the air warmed by the body temperature or the like of the occupant P who has left the seat is sucked into the lower ventilation path 10 from the plurality of lower suction ports 11 via the lower cushion portion 31A. At this time, the cooled and dehumidified conditioned air CA from the vehicle air conditioner 40 is sucked from the space above the seat surface portion 31 toward the lower cushion portion 31A.

  That is, on the surface of the lower cushion portion 31 </ b> A, the air warmed by the body temperature of the occupant P is replaced with air cooled and dehumidified by the vehicle air conditioner 40. Thereby, according to the said seat air-conditioning system 100, the seat air-conditioning apparatus 1 and the vehicle air-conditioning apparatus 40 are operated in cooperation, so that warmth and stuffiness in the seat surface portion 31 can be quickly eliminated, and comfort is improved. Can be recovered early.

  Similarly, when the operation of the second blower 25 is started in step S14, the second blower 25 draws the conditioned air CA supplied in front of the backrest portion 32 through the upper cushion portion 32A. The air is sucked into the upper ventilation path 20 from the mouth 21. The second blower 25 discharges the air sucked into the upper ventilation path 20 from the upper air outlet 22 to the back side of the backrest 32.

  Thereby, the air warmed by the body temperature of the occupant P who has left the seat is sucked into the upper ventilation path 20 from the plurality of upper suction ports 21 via the upper cushion portion 32A. At this time, the cooled and dehumidified conditioned air CA from the vehicle air conditioner 40 is sucked from the space in front of the backrest 32 toward the upper cushion 32A.

  That is, on the surface of the upper cushion portion 32A, the air heated by the body temperature or the like of the occupant P is replaced with air cooled and dehumidified by the vehicle air conditioner 40. Thereby, according to the said seat air-conditioning system 100, the seat air-conditioner 1 and the vehicle air-conditioner 40 can be operated in cooperation, so that warmth and stuffiness in the backrest 32 can be quickly eliminated, and comfort is improved. Can be recovered early.

  In step S15, it is determined whether or not an operation stop condition for stopping the operations of the seat air conditioner 1 and the vehicle air conditioner 40 is satisfied. The operation stop condition in the second embodiment is that the surface temperature Ts is lower than the operation stop temperature ST, as in step S6 of the first embodiment described above.

  When the surface temperature Ts is lower than the operation stop temperature ST, it is considered that the comfort of the seat 30 lowered by the occupant P who has left the seat is sufficiently recovered, and the process proceeds to step S16. When that is not right, a process is returned to step S14, and the operation | movement of the seat air conditioner 1 and the vehicle air conditioner 40 is continued.

  The operation stop condition in the second embodiment can adopt a condition different from the condition related to the surface temperature Ts mentioned in the first embodiment. For example, the conditions given in the fifth modification of the first embodiment can be employed as the operation stop conditions in step S15.

  In step S <b> 16, the operation of the seat air conditioner 1 and the vehicle air conditioner 40 is terminated when the operation stop condition is satisfied. At this time, the surface temperature Ts and the surface humidity Hs in the seat surface portion 31 and the backrest portion 32 are reduced to the same level as the room temperature Tr and the room humidity Hr. Therefore, even when the occupant P is newly seated, the person leaves the seat. Sufficient comfort can be ensured without the passenger P feeling warm or damp.

  As shown in FIGS. 8 and 9, according to the seat air conditioner 1, when the occupant P leaves the seat 30, the vehicle air conditioner is controlled by cooperative control of the seat air conditioner 1 and the vehicle air conditioner 40. The conditioned air CA from the device 40 is blown through the lower cushion portion 31A and the upper cushion portion 32A.

  Thereby, the said seat air conditioner 1 can discharge the warmth and stuffiness resulting from the body temperature of the occupant P who has left the seat from the surface of the seat 30 as early as possible from the time when the occupant P has left the seat. Therefore, even when a new occupant P is seated immediately after the occupant P leaves the seat 30, it is possible to prevent the user from feeling uncomfortable due to warmth or the like.

  At this time, the vehicle air conditioner 40 operates in the cooling mode and supplies the conditioned air CA that has been cooled and dehumidified to the seat 30 in the passenger compartment C. Thereby, according to the said seat air-conditioning system 100, since the steamed air heated by the body temperature etc. of the passenger | crew P who left the seat can be replaced with the conditioned air CA cooled and dehumidified by the vehicle air conditioner 40, The comfort of the seat 30 can be recovered at an early stage.

  As described above, according to the seat air-conditioning system 100 according to the second embodiment, the same effects as the first embodiment can be obtained in the same manner as the first embodiment. it can.

  And the seat 30 in 2nd Embodiment is comprised so that the passenger | crew P can seat. For this reason, when the occupant P is seated on the seat 30, the lower cushion portion 31A and the upper cushion portion 32A are warmed and steamed due to the body temperature and sweating of the occupant P. Is assumed.

  According to the seat air conditioning system 100 according to the second embodiment, when it is determined in step S12 that the occupant P has left the seat 30, the seat air conditioner 1 and the vehicle air conditioner 40 are operated, While the conditioned air CA is supplied from the vehicle air conditioner 40, the seat air conditioner 1 blows air through the lower cushion portion 31A and the upper cushion portion 32A.

  Accordingly, the seat air conditioning system 100 uses the conditioned air CA from the vehicle air conditioner 40 to convert the steamed air heated by the body temperature and sweating of the occupant P who has left the seat into the lower cushion portion 31A and the upper cushion portion 31A. It can be excluded from the cushion portion 32A.

  That is, according to the seat air conditioning system 100, when the occupant P leaves the seat 30, the seat air conditioner 1 and the vehicle air conditioner 40 cooperate with each other to influence the body temperature of the occupant P. The lowered comfort of the seat 30 can be recovered early. As a result, the seat air-conditioning system 100 can provide the new passenger P with a comfortable seat 30 that is not affected by the warmth or stuffiness of the previous passenger P.

  Further, the seat air conditioning system 100 according to the second embodiment operates the vehicle air conditioner 40 in the cooling mode in step S14 when the occupant P leaves the seat 30, and the lower cushion portion 31A, The operation of the seat air conditioner 1 is controlled so that air is sucked into the lower ventilation path 10 and the upper ventilation path 20 via the upper cushion portion 32A.

  As a result, as shown in FIG. 9, in the seat surface portion 31, the cooled and dehumidified conditioned air CA supplied from the vehicle air conditioner 40 passes through the lower cushion portion 31 </ b> A to the inside of the lower ventilation passage 10. Sucked into. And in the backrest part 32, the conditioned air CA from the vehicle air conditioner 40 is sucked into the upper ventilation path 20 via the upper cushion part 32A.

  That is, according to the seat air conditioning system 100 according to the second embodiment, by using the conditioned air CA that has been cooled and dehumidified by the vehicle air conditioner 40, the comfort that has decreased due to the body temperature of the occupant P who has left the seat, It can be recovered earlier.

(Other embodiments)
As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to embodiment mentioned above at all. That is, various improvements and modifications can be made without departing from the spirit of the present invention. For example, you may combine each embodiment mentioned above suitably. The above-described embodiment can be variously modified as follows, for example.

  (1) In the embodiment described above, the seat air conditioner 1 is intended for the seat 30 disposed in the vehicle compartment C of the vehicle, but is not limited to this mode. The seat air-conditioning apparatus according to the present invention can be applied to various configurations as long as it is a chair-like configuration configured to be seated.

  For example, the present invention can be applied to a shared office chair, a sofa arranged in a waiting room, and the like. The present invention can also be applied to seats in taxis, buses, trains and the like.

  (2) Moreover, in embodiment mentioned above, it has the 1st air blower 15 arrange | positioned at the seat surface part 31 side and the 2nd air blower 25 arrange | positioned at the backrest part 32 side as an air blower which comprises the seat air conditioner 1. However, the present invention is not limited to this mode. That is, the number of blowers constituting the seat air conditioner can be changed as appropriate according to the configuration and the like. For example, a single blower can be used.

  (3) In the above-described embodiment, the seat air conditioner 1 is configured by the blowers such as the first blower 15 and the second blower 25 and the ventilation passages such as the lower ventilation passage 10 and the upper ventilation passage 20. However, it is not limited to this configuration. In addition to these configurations, it is also possible to add additional configuration devices.

  As a component apparatus added to a sheet | seat air conditioner, the refrigerating cycle apparatus for making the ventilation air which passes a ventilation path with an air blower into an air conditioning wind can be mentioned. In this case, the refrigeration cycle apparatus is desirably housed in one housing in order to use a space around the seat (for example, a space below the seating surface).

  (4) In the above-described embodiment, the seating sensor 51 is configured by a weight sensor. However, various detection methods can be employed as long as the occupant P seated on the seat 30 can be detected. .

  As the seating sensor 51, for example, an infrared sensor having the seat 30 as a detection range may be employed. Further, as a seating sensor, it is possible to employ a configuration in which image processing is performed on an image including the seat 30 in the imaging range, and the presence or absence of the passenger P with respect to the seat 30 is determined by image recognition.

  (5) Moreover, in 2nd Embodiment mentioned above, the operation | movement aspect of the seat air conditioner 1 and the vehicle air conditioner 40 is set according to the seating condition of the passenger | crew P who left the seat like step S4 of 1st Embodiment. It may be changed. For example, the higher the surface temperature Ts or the like, the lower the temperature of the conditioned air CA supplied from the vehicle air conditioner 40 may be adjusted. Similarly to the first embodiment, the higher the surface temperature Ts or the like, the larger the amount of air blown by the first blower 15 and the second blower 25.

  (6) Further, in the above-described embodiment, the vehicle air conditioner 40 is configured to operate in the cooling mode in step S14. However, if the conditioned air CA that has been cooled and dehumidified can be supplied, It is also possible to adopt other operation modes.

  For example, the dehumidifying heating mode may be employed as the operation mode of the vehicle air conditioner 40 in this case. The dehumidifying and heating mode is an operation mode in which the conditioned air CA cooled and dehumidified by heat exchange with the low-pressure refrigerant in the evaporator 44 is supplied by being heated by a heater core or the like. Even in this operation mode, the stuffiness caused by the occupant P leaving the seat can be eliminated.

DESCRIPTION OF SYMBOLS 1 Seat air conditioner 10 Lower side ventilation path 15 1st air blower 20 Upper side air flow path 25 2nd air blower 30 Seat 31 Seat surface part 32 Backrest part 50 Control part 51 Seating sensor

Claims (12)

A seat (30) provided with seat surface portions (31A, 32A) having contact with the seated seated person (P) and having air permeability;
Blowers (15, 25) for blowing air through the sheet surface portion;
Inside the seat, connecting the blower to the seat surface portion, and a ventilation path (10, 20) through which air by operation of the blower flows,
A seat detection unit (51) for detecting a seated person seated on the seat;
A control unit (50) for controlling the operation of the blower,
The controller is
An absence determination unit (50A) for determining whether or not the seated person has left the seat according to a change in a detection result by the seat detection unit;
A blow control unit (50B) for controlling the operation of the blower so as to blow air through the seat surface portion when it is determined by the leave determination unit that the seated person has left the seat; Seat air conditioner having The control unit relates to the seated person who has left the seat, and determines whether or not the seating condition when the seated person is seated on the seat satisfies a predetermined standard condition. (50C)
The blower control unit controls the operation of the blower so as to blow air through the seat surface portion when the seating state determination unit determines that the seating state satisfies the reference condition. The seat air conditioner described in 1.   The reference condition is that the surface temperature (Ts) of the seat surface portion when the seated person leaves the seat is higher than a predetermined reference surface temperature (KTs). Seat air conditioner.   The reference condition is that the surface humidity (Hs) of the seat surface portion when the seated person leaves the seat is higher than a predetermined reference surface humidity (KHs). Seat air conditioner.   The seat air conditioner according to claim 2, wherein the reference condition is that a seating time (t) in which the seated person who has left the seat is seated on the seat is longer than a predetermined reference seating time (Kt). .   The said ventilation control part controls the action | operation of the said air blower so that the amount of ventilations becomes so large that the surface temperature of the said sheet | seat when the said seated person leaves a seat is high. Seat air conditioner.   The said ventilation control part controls the action | operation of the said air blower so that the amount of ventilations becomes so large that the surface humidity of the said sheet | seat when the said seated person leaves a seat is high. Seat air conditioner.   The seat air conditioner according to any one of claims 1 to 5, wherein the air blowing control unit controls the operation of the air blower so that the air blowing amount increases as the seated time of the seated person who leaves the seat increases.   The blower control unit stops the operation of the blower when the surface temperature of the sheet is lower than an operation stop temperature (ST) determined based on an ambient temperature (Tr) around the sheet. The seat air conditioner according to any one of 8.   The blower control unit stops the operation of the blower when the surface humidity of the sheet is lower than an operation stop humidity (SH) determined based on an atmospheric humidity (Hr) around the sheet. The seat air conditioner according to any one of 8. An air conditioner for a vehicle (40) for blowing conditioned air (CA) whose temperature is adjusted toward the inside of the passenger compartment (C) of the vehicle;
A seat air conditioner (1) that is disposed on a seat (30) disposed inside the passenger compartment and that performs air conditioning for a position of a seated person (P) seated on the seat;
A seating detection unit (51) for detecting the seated person seated on the seat;
A control device (60) for controlling the operation of the vehicle air conditioner and the seat air conditioner,
The seat air conditioner
Blowers (15, 25) that contact the seated person seated on the seat and blow air through seat surface portions (31A, 32A) having air permeability,
In the inside of the seat, the air passage (10, 20) that connects the blower to the seat surface portion and through which the air by the operation of the blower flows has,
The controller is
An absence determination unit (60A) for determining whether or not the seated person has left the seat according to a change in a detection result by the seat detection unit;
The seat control unit controls the operation of the vehicle air conditioner so that the conditioned air is blown to the seat when it is determined that the seated person has left the seat. A seat air conditioning system comprising: an operation control unit (60B) that controls the operation of the seat air conditioner so as to blow air through the surface portion. The operation controller is
When the absence determination unit determines that an occupant has left the seat, the conditioned air cooled and dehumidified by the refrigeration cycle (43) of the vehicle air conditioner is blown to the seat. , Controlling the operation of the vehicle air conditioner,
The seat air conditioning system according to claim 11, wherein the operation of the blower in the seat air conditioner is controlled so that the conditioned air blown from the vehicle air conditioner passes through the seat surface portion and the ventilation path in this order.

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