CN102733150B - Clothes processor - Google Patents

Abstract

The invention provides a clothes processor. The clothes processor comprises a main basket body accomodating the driving source of a processing tank accomodating clothes and a driving processing tank, a support part damping the vibration, a drainage system discharging clothes washing water outside the main basket body and a circulating system for circulating the drying air. The circulating system comprises a dehumidifying part for dehumidifying the drying air and a sensing component measuring the drying degree of clothes. A guide pipe specifying the flow path for the air to flow comprises an inflow port for the washing water supplied to the processing tank and the drying air to flow therein. The drainage system comprises a drainage pipe guiding the clothes washing water towards the outside of the main basket body and a connecting part connecting the inflow port and the drainage pipe. The drainage pipe comprises a fixing part fixed on the main basket body. The sensing component comprises a temperature sensor for measuring the temperature of dehumidifying water flowed into the fixing part through the connecting part. In this way, the sensing component can be stably retained.

Description

Device for clothing processing

Technical field

The present invention relates to and clothing done washing and the device for clothing processing of the process such as oven dry.

Background technology

Device for clothing processing clothing being carried out to laundry treatment or drying and processing typically comprises the circulatory system making the oven dry air circulation supplying drying clothes.The circulatory system such as comprises the heat exchanger carrying out heat exchange with oven dry air.

Patent document 1 discloses a kind of device for clothing processing comprising tube type heat exchanger.The dehumidifying water be supplied in heat exchanger is used to dehumidify to oven dry air.Thereafter, the oven dry air heated by heater is supplied to the treatment trough containing clothing.

According to the disclosure of patent document 1, use the temperature sensor of temperature for measuring dehumidifying water for detecting the oven dry degree of washings.

Temperature sensor disclosed in patent document 1 be detect the oven dry degree of washings measured just with the temperature of drying air and carry out the dehumidifying water after heat exchange.Therefore, temperature sensor is arranged near the drying tank of drying clothes.

Drying tank comprises the rotary part (such as impeller or swing roller) that clothing is rolled.Vibration from rotary part makes being arranged on of temperature sensor physically become unstable.Being provided with of instability of temperature sensor may cause temperature measurement accuracy to reduce.

Patent document 1: No. 2000-397, Japanese Laid-Open Patent Publication

Summary of the invention

The object of the present invention is to provide a kind of device for clothing processing with the structure of the sensing element that stably can be kept for the dryness fraction measuring clothing.

Device for clothing processing involved in the present invention, comprising: treatment trough, for accommodating clothing; Drive source, drives described treatment trough; Main basket, accommodates described treatment trough and described drive source; Support component, supports described treatment trough and decay to be passed to the vibration of described main basket from described treatment trough; Drainage system, discharges the laundry water for the described clothing washed or in treatment trough described in rinsing outside described main basket; And the circulatory system, make the oven dry air circulation of the described clothing in the described treatment trough of oven dry, wherein, the described circulatory system comprises the sensing element of the dehumidifying section dehumidified to described oven dry air and the dryness fraction measuring described clothing, and described dehumidifying section comprises: the guiding tube comprising the inner face of the stream of the described oven dry air flowing of regulation; And for supplying the feed water inlet be applied to the dehumidifying water that described oven dry air dehumidifies in described stream, wherein, described guiding tube comprises the inflow entrance that the described laundry water that is supplied to described treatment trough and described oven dry air flow into, and described drainage system comprises: the drainpipe guiding described laundry water outside described main basket; And connect the attaching parts of described inflow entrance and described drainpipe, wherein, described drainpipe comprises the fixed part being fixed in described main basket, and described sensing element is comprised for measuring the temperature sensor being flowed into the temperature of the described dehumidifying water in described fixed part by described attaching parts.

According to described structure, device for clothing processing involved in the present invention stably can be kept for the sensing element of the dryness fraction measuring clothing.

Accompanying drawing explanation

Fig. 1 is the approximate three-dimensional map of the dryer of an embodiment.

Fig. 2 is the front view of the dryer shown in Fig. 1.

Fig. 3 is the top view of the dryer shown in Fig. 1.

Fig. 4 is the stereogram of the internal structure representing the dryer shown in Fig. 1.

Fig. 5 is the general profile chart of the internal structure representing the dryer shown in Fig. 1.

Fig. 6 is the top view of the internal structure representing the dryer shown in Fig. 1.

Fig. 7 is the side view of the heat exchanger that the dryer shown in Fig. 1 has.

Fig. 8 is the general configuration diagram of filter, pipe assembly, pressure fan, heater and the pipeline that the dryer shown in Fig. 1 has.

Fig. 9 is the rearview of the heat exchanger that has of the dryer shown in Fig. 1 and filter.

Figure 10 is the sectional view of the filter that the dryer shown in Fig. 1 has.

Figure 11 is the sectional view of the downside assembly that the filter shown in Figure 10 has.

Figure 12 is the top view of the dryer shown in Fig. 1.

Figure 13 is the stereogram of the upside assembly that the filter shown in Figure 10 has.

Figure 14 is the sectional view of the upside assembly shown in Figure 13.

Figure 15 is the front view of the upside assembly shown in Figure 13.

Figure 16 is the right side view of the first basket that the upside assembly shown in Figure 13 has.

Figure 17 is the general profile chart of the upside assembly shown in Figure 13.

Figure 18 is the outline elevation of the upside assembly shown in Figure 13.

Figure 19 is the first basket representing that the upside assembly shown in Figure 13 has and the figure rotating projection.

Figure 20 is the figure of the second basket and the support tube representing that the upside assembly shown in Figure 13 has.

Figure 21 is the figure of the first basket and the second basket representing that the upside assembly shown in Figure 13 has.

Figure 22 represents that the first support tube of the second basket shown in Figure 21 and first of the first basket rotate the figure of projection.

Figure 23 is the general profile chart of the second basket shown in Figure 21.

Figure 24 is the stereogram of the upside assembly shown in Figure 13.

Figure 25 is the figure representing the upside assembly shown in Figure 24.

Figure 26 is the skeleton diagram of the heat exchanger shown in Fig. 7.

Figure 27 is the approximate three-dimensional map of the second housing body of the heat exchanger shown in Figure 26.

Figure 28 (a) is the enlarged drawing of the first rib of the second housing body shown in Figure 27.

Figure 28 (b) is the general profile chart of the second housing body shown in Figure 27.

Figure 29 is the outline elevation of the second housing body shown in Figure 27.

Figure 30 is the outline longitudinal section of the heat exchanger shown in Figure 26.

Figure 31 is that the outline on the top of the heat exchanger shown in Figure 30 amplifies longitudinal section.

Figure 32 is the outline sectional elevation on the top of the heat exchanger shown in Figure 30.

Figure 33 is the outline enlarged drawing of the bottom of the second housing body shown in Figure 27.

Figure 34 is the outline amplification view of the syndeton between tank and heat exchanger.

Figure 35 is the outline right side view of the filter assemblies that the dryer shown in Fig. 1 has.

Figure 36 is the general profile chart of the filter assemblies along the A-A line shown in Figure 35.

Figure 37 is the curve map roughly representing the installation site of temperature sensor and the relation of detection sensitivity.

Detailed description of the invention

Below, be described with reference to the embodiment of accompanying drawing to device for clothing processing.In addition, the expression that uses in below illustrating " on ", D score, the direction such as " left side " or " right side " term be only for clearly stating, be not used for the principle of restriction device for clothing processing.

(overall structure of device for clothing processing)

Fig. 1 is the approximate three-dimensional map of the dryer also except drying function with function of washing clothes.Fig. 2 is the front view of the dryer shown in Fig. 1.Fig. 3 is the top view of the dryer shown in Fig. 1.

In the present embodiment, the dryer 100 shown in Fig. 1 to Fig. 3 is exemplified as carrying out the device for clothing processing of the various process such as drying and processing, laundry treatment to clothing.

Dryer 100 comprises collecting for carrying out the main basket 110 of the substantially rectangular box like of the various parts (such as, treatment trough described later, for driving the CD-ROM drive motor for the treatment of trough) of drying and processing and laundry treatment.Main basket 110 comprise face wall 111, face wall 111 opposition side back face wall 112, stand upright on left side wall 113 between face wall 111 and back face wall 112 and right side wall 114.Main basket 110 also comprises the roof 115 surrounded by the upper limb of face wall 111, back face wall 112, left side wall 113 and right side wall 114 and the diapire 116 surrounded by the lower edge of face wall 111, back face wall 112, left side wall 113 and right side wall 114.

Dryer 100 also comprises the guidance panel 120 being arranged on face wall 111 top.User by guidance panel 120 input the information relevant to the action of dryer 100 (such as with for washing, rinsing, dehydration, the information of being correlated with during oven dry and the information of being correlated with used washing agent).

Dryer 100 also comprises the door body 130 be installed in rotation in face wall 111.User can beat opening door body 130 and drop into clothing in main basket 110, or takes out the clothing in main basket 110.

Fig. 4 is the stereogram of the dryer 100 representing each parts be arranged in main basket 110.Dryer 100 shown in Fig. 4 eliminates face wall 111, back face wall 112, left side wall 113, right side wall 114 and roof 115.Fig. 5 is the general profile chart of the dryer 100 representing each parts be arranged in main basket 110.Fig. 1, Fig. 4 and Fig. 5 is utilized to be described dryer 100 further.

As shown in Figure 4, dryer 100 comprises the treatment trough 200 of collecting clothing.The input port 201 to face wall 111 opening is formed at treatment trough 200.As being described relatively with Fig. 1, user can beat opening door body 130, drops into clothing via input port 201 in treatment trough 200.Or user can beat opening door body 130, take out clothing via input port 201 from treatment trough 200.

As shown in Figure 5, treatment trough 200 comprises: storage is used for the tank 210 of the laundry water of washing clothes; And the swing roller 220 be arranged in tank 210.Swing roller 220 comprise roughly cylindric perisporium 221 and with input port 201 diapire 222 in opposite directions.Tank 210 comprises: the roughly cylindric perisporium 211 surrounding the perisporium 221 of swing roller 220; And along swing roller 220 diapire 222 and formed diapire 212.Swing roller 220 is arranged with tank 210 is roughly concentric.

Dryer 100 also comprises: from the diapire 222 of swing roller 220 run through tank 210 diapire 212 and from the outstanding rotating shaft 231 of diapire 212; Be arranged on the CD-ROM drive motor 230 of the below of tank 210; And for the driving belt 232 of driving force from CD-ROM drive motor 230 to rotating shaft 231 that transmit.When CD-ROM drive motor 230 works, driving force is passed to swing roller 220 by driving belt 232 and rotating shaft 231, thus swing roller 220 rotates in tank 210.In the present embodiment, CD-ROM drive motor 230 is exemplified as drive source.

As shown in Figure 4, dryer 100 also comprises: connect the diapire 116 of main basket 110 and the damping means 240 for the treatment of trough 200; And connect the roof 115 of main basket 110 and the sprung parts 245 for the treatment of trough 200.In main basket 110, the vibration attenuation that the damping means 240 of support treatment trough 200 and sprung parts 245 make treatment trough 200 produce along with the rotation of swing roller 220.Therefore, the vibration from treatment trough 200 is passed to main basket 110 hardly.In the present embodiment, damping means 240 and sprung parts 245 are exemplified as support component.

As shown in Figure 4, dryer 100 also comprises control device 250.Control device 250 controls the various actions of dryer 100.Such as, when user operates guidance panel 120 and indicates dryer 100 to carry out oven dry action, export control signal and CD-ROM drive motor 230 is worked.

As shown in Figure 1, dryer 100 also comprises the feed water inlet 301 for supplying water in main basket 110.In the present embodiment, feed water inlet 301 appears at the corner portion formed with the left border 118 of roof 115 by the back side edge 117 of roof 115.

As shown in Figure 4, dryer 100 also bag mouth be arranged on below roof 115 for water assembly 300.The control valve 310 be connected with feed water inlet 301 and the basket 320 comprising the outside being fixed with control valve 310 is comprised for water assembly 300.The stream (not shown) for supplying water to treatment trough 200 is formed in basket 320.

Dryer 100 also comprises and carries out heat exchange with oven dry air, to drying the heat exchanger 400 that dehumidifies of air.For in the basket 320 of water assembly 300, be not only formed with the stream for supplying water to treatment trough 200, but also when being formed for dehumidifying for reply oven dry air the stream of dehumidifying water.Control valve 310 switches and to supply water from feed water inlet 301 or stop to supply water in basket 320 under the control of control device 250.In addition, control valve 310 opening and closing is used for supplying the stream of water and the stream for supplying dehumidifying water to treatment trough 200.Such as, when user guidance panel 120 is operated and indicate start washing procedure time, control valve 310 allows the inflow of water in basket 320 under the control of control device 250.And control valve 310 opens the stream for supplying water to treatment trough 200.Its result, water is supplied in treatment trough 200.Or, when user guidance panel 120 is operated and indicate start baking operation time, control valve 310 allows the inflow of water in basket 320 under the control of control device 250.And control valve 310 opens the stream supplying dehumidifying water for heat exchanger 400.Its result, dehumidifying water is supplied in heat exchanger 400, and oven dry air is dehumidified.

Basket 320 comprises adjutage 321 outstanding to the right.When control valve 310 open supply the stream of dehumidifying water for heat exchanger 400 time, dehumidifying water is by connecting adjutage 321 and the tube connector (not shown) of heat exchanger 400 and inflow heat exchanger 400.

The accepting box 330 be arranged in basket 320 is also comprised for water assembly 300.The softener used in the washing agent used in washing procedure or rinsing process is contained in accepting box 330.

As shown in Figure 1, accepting box 330 comprises the handle portion 331 formed in the mode can inserting user's finger.User can use handle portion 331 from pull-out accepting box 330 in basket 320.Its result, the inside of accepting box 330 is exposed to outside main basket 110.Thereafter, user can drop into washing agent or softener and be pushed in basket 320 by accepting box 330 in accepting box 330.

When the control valve 310 illustrated relatively with Fig. 4 is opened for supplying the stream of water to treatment trough 200, the water flowed in basket 320 mixes with the washing agent in accepting box 330 or softener.Its result, in washing procedure, the washings that the washing agent in accepting box 330 mixes with the water supplied from feed water inlet 301 are supplied to treatment trough 200.In addition, in rinsing process, the mixed liquor that the softener in accepting box 330 mixes with the water supplied from feed water inlet 301 is supplied to treatment trough 200.

As shown in Figure 5, dryer 100 also comprises the water supply pipe 350 on the top connecting the diapire 212 supplying water assembly 300 and tank 210.When control valve 310 is opened for supplying the stream of water to treatment trough 200, the water supplied from feed water inlet 301 is supplied in treatment trough 200 by water supply pipe 350.

Dryer 100 also comprises: the drainpipe 360 being connected to the bottom of the perisporium 211 of tank 210; And under the control of control device 250 draining valve 361 of opening and closing drainpipe 360.

As shown in Figure 4, water discharge outlet 362 is formed with in diapire 116 side of main basket 110.Drainpipe 360 is communicated to water discharge outlet 362.When drainpipe 360 opened by draining valve 361, the water in treatment trough 200 is expelled to outside main basket 110 via water discharge outlet 362.In the present embodiment, drainpipe 360, draining valve 361 and water discharge outlet 362 are exemplified as drainage system.

As shown in Figure 5, heat exchanger 400 is connected to the bottom of the diapire 212 of tank 210.Therefore, finally flow in treatment trough 200 from the dehumidifying water being supplied to heat exchanger 400 for water assembly 300.When drainpipe 360 opened by draining valve 361, dry the dehumidifying water used in the dehumidifying of air and be also expelled to outside main basket 110 via water discharge outlet 362.

Drainpipe 360 comprises filter assemblies 500.Drainpipe 360 is connected to water discharge outlet 362 via filter assemblies 500.Filter assemblies 500 comprises for the filter element 510 from the water removing Soft flocks flow through in drainpipe 360 or other foreign matters.Therefore, the water that component 510 eliminates the foreign matters such as Soft flocks is after filtration discharged from water discharge outlet 362.

Filter assemblies 500 is fixed on face wall 111.As being described relatively with Fig. 4, damping means 240 and sprung parts 245 make the vibration attenuation from treatment trough 200, and therefore, filter assemblies 500 is stably held in face wall 111.In the present embodiment, filter assemblies 500 is exemplified as fixed part.

As shown in Figure 5, filter element 510 comprises the handle portion 511 outstanding to face wall 111.As shown in Figure 1, face wall 111 over cap 251 that comprises Coverage Control device 250 and the door portion 252 that is installed in rotation on over cap 251.Filter assemblies 500 is fixed on over cap 251.When user beats door opening portion 252, handle portion 511 exposes.User can pinch handle portion 511 and take out filter element 510.

Dryer 100 also comprises the circulatory system 600 allowed for the oven dry air circulation of the clothing in drying and processing groove 200.The circulatory system 600 not only comprises above-mentioned heat exchanger 400, but also comprises: make the pressure fan 610 in oven dry air inflow treatment trough 200; Specify the pipeline 615 of the stream from the oven dry air till pressure fan 610 to treatment trough 200; And to the heater 620 that the oven dry air flowing to treatment trough 200 from pressure fan 610 heats.

As shown in Figures 4 and 5, pipeline 615 is connected to the perisporium 211 of tank 210 near input port 201.When pressure fan 610 works, dry air and flowed in treatment trough 200 by pipeline 615.Heater 620 heats the oven dry air flowing to treatment trough 200 from pressure fan 610, therefore higher to the clothing blowout temperature in treatment trough 200 oven dry air.Its result moisture evaporates from clothing.

The oven dry air comprising the moisture of evaporation flows into the heat exchanger 400 be connected with the diapire 212 of tank 210 subsequently.As mentioned above, flow down in heat exchanger 400 from the dehumidifying water supplied for water assembly 300, the oven dry air therefore in inflow heat exchanger 400 is dehumidified.In the present embodiment, heat exchanger 400 is exemplified as dehumidifying section.

The circulatory system 600 also comprises the filter 700 be arranged between pressure fan 610 and heat exchanger 400.Heat exchanger 400 comprises the bellows 414 be connected with filter 700.Soft flocks are separated from being blown the clothing of drying air.The Soft flocks be separated flow to filter 700 by heat exchanger 400 and bellows 414 subsequently.Filter 700 removes Soft flocks from oven dry air.

As shown in Figure 5, the circulatory system 600 also comprises the pipe assembly 660 guiding the oven dry air flowing to pressure fan 610 from filter 700.Pressure fan 610 makes to become negative pressure in pipe assembly 660, and therefore, the oven dry air that device 700 removes Soft flocks after filtration flows to pressure fan 610 by pipe assembly 660.Accordingly, the circulatory system 600 forms the circulating path of drying air in main basket 110.

(syndeton of filter and heat exchanger)

Fig. 6 is the top view of the internal structure representing dryer 100.The decomposition method of Fig. 1 and Fig. 6 to the main basket 110 of dryer 100 is utilized to be described.

The roof 115 formed above main basket 110 uses the fixtures such as screw to be fixed on the perisporiums such as face wall 111, back face wall 112, left side wall 113 and right side wall 114.The operator placed under repair to dryer 100 or overhaul can unload fixture and remove roof 115 from the perisporium of main basket 110.Accordingly, the inside of operator's observable dryer 100.

Fig. 7 is the side view of heat exchanger 400.The flowing of Fig. 5 and Fig. 7 to the oven dry air flowing to filter 700 from heat exchanger 400 is utilized to be described.

Heat exchanger 400 comprises the heat-exchange tube 410 carrying out heat exchange with oven dry air.Heat-exchange tube 410 comprises regulation for the inner face 411 of drying the stream that air flows.Heat exchanger 400 also comprises the feed water inlet 420 for supplying the roughly cylindrical shape be applied to the dehumidifying water that oven dry air dehumidifies to the stream of heat-exchange tube 410 defined.Feed water inlet 420 comprise bottom the first feed water inlet 421, be formed in the second feed water inlet 422 of the top of the first feed water inlet 421 and be formed in the 3rd feed water inlet 423 of top of the second feed water inlet 422.In the present embodiment, heat-exchange tube 410 is exemplified as guiding tube.

Heat-exchange tube 410 comprises inflow entrance 412 and is formed in the exhaust outlet 413 of top of inflow entrance 412.Heat-exchange tube 410 extends to roof 115 between inflow entrance 412 and exhaust outlet 413.As shown in Figure 5, the inflow entrance 412 being formed in the lower end of heat exchanger 400 is connected to the diapire 212 of tank 210.In baking operation, the oven dry air sent to treatment trough 200 is flowed in heat-exchange tube 410 by inflow entrance 412.In addition, during washing procedure or rinsing process, be supplied to water in treatment trough 200 (washings or comprise the aqueous solution of softener) and flowed in heat-exchange tube 410 by inflow entrance 412.

The oven dry air flowed in heat-exchange tube 410 is discharged from the exhaust outlet 413 of the upper end being formed in heat-exchange tube 410.Thereafter, dry air and be back to treatment trough 200 by filter 700, pressure fan 610 and heater 620.

Fig. 8 is the general configuration diagram of filter 700, pipe assembly 660, pressure fan 610, heater 620 and pipeline 615.Fig. 1, Fig. 4 to Fig. 8 supply to dehumidifying water heat exchanger 400 is utilized to be described.

By the drying and processing of the clothing in treatment trough 200 and the heat exchange in heat exchanger 400, dry the temperature of temperature lower than the oven dry air after firm heater via 620 heating of air.Therefore, in the path till filter 700 to pressure fan 610, easily condensation is produced.

Pipe assembly 660 comprises: the diapire 661 tilted downwards towards filter 700; And be connected to the tube connector 662 of the lower end of diapire 661 and the 3rd feed water inlet 423 of heat exchanger 400.To condense in pipe assembly 660 and the dew be attached on the inner face of pipe assembly 660 flows down along diapire 661 under gravity.Thereafter, dew is supplied to heat exchanger 400 by tube connector 662 and the 3rd feed water inlet 423 as dehumidifying water.

In filter 700, the dew of condensation drops to pipe assembly 660 because of Action of Gravity Field and oven dry air.Thereafter, dew along pipe assembly 660 diapire 661 and flow down, eventually through tube connector 662 and the 3rd feed water inlet 423 as dehumidifying water be supplied to heat exchanger 400.

Pressure fan 610 comprises: be arranged on the fan 611 in the stream of drying air; And the CD-ROM drive motor 612 that fan 611 is rotated.Be attached to dew on fan 611 and drop to pipe assembly 660 because of the rotation of Action of Gravity Field and fan 611.Thereafter, dew along pipe assembly 660 diapire 661 and flow down, eventually through tube connector 662 and the 3rd feed water inlet 423 as dehumidifying water be supplied to heat exchanger 400.

Pipe assembly 660 also comprises the check-valves 663 of the bottom being arranged on diapire 661.Check-valves 663 suppresses to dry air and flows directly into pipe assembly 660 from heat exchanger 400.

As being described relatively with Fig. 4, the adjutage 321 that the water supplied from feed water inlet 301 passes through as dehumidifying water from the basket 320 for water assembly 300 is outstanding is discharged.The tube connector be connected with adjutage 321 is connected to the first feed water inlet 421 and the second feed water inlet 422 of heat exchanger 400.

Be supplied to the dehumidifying waterside in heat exchanger 400 and carry out heat exchange by inner face 411 leading edge of heat-exchange tube 410 with oven dry air.Its result, oven dry air is dehumidified.The dehumidifying water flowed down along the inner face 411 of heat-exchange tube 410 is finally discharged from heat exchanger 400 via the inflow entrance 412 of heat exchanger 400 lower end.

As shown in Figure 6, the heat exchanger 400 second housing body 440 that comprises the first shell body 430 and be arranged between the first shell body 430 and the back face wall 112 of main basket 110.Second housing body 440 is arranged along back face wall 112.As shown in Figure 7, second housing body 440 is overlapped in the first shell body 430 and forms heat-exchange tube 410.Inflow entrance 412 and exhaust outlet 413 are formed on the first shell body 430.Feed water inlet 420 is formed on second housing body 440.

First shell body 430 and second housing body 440 form the stream of roughly C sigmoid.From the stream of oven dry air by bending that the inflow entrance 412 being formed in heat exchanger 400 lower end flows into, and discharge from the exhaust outlet 413 being formed in heat exchanger 400 upper end.

Horizontal line HL and the centre line L 1 in roughly cylindric exhaust outlet 413 have been shown in Fig. 7.Heat exchanger 400 it is preferable that and to be arranged in main basket 110 in the mode that the centre line L 1 of exhaust outlet 413 is substantially vertical with horizontal line.Therefore, the upper portion of almost parallel with the centre line L 1 of exhaust outlet 413 second housing body 440 along main basket 110 back face wall 112 and formed.

Fig. 9 is the rearview of the syndeton represented between heat exchanger 400 and filter 700.Fig. 1, Fig. 6, Fig. 7 and Fig. 9 is utilized to be described the syndeton between heat exchanger 400 and filter 700.

As shown in Figure 9, connecting exhaust outlet 413 uses fixed band 416 to be fixed on exhaust outlet 413 with the lower end of the bellows 414 of filter 700.Similarly, the upper end of bellows 414 also uses fixed band 417 to be fixed on filter 700.

As shown in figs. 6 and 9, filter 700 relative to exhaust outlet 413 centre line L 1 and to horizontal direction (leaving the direction of right side wall 114) skew arrange.Being described as relevant to Fig. 6, operator can unload roof 115.Thereafter, operator can unload bellows 414 fixing in the fixed band 416,417 that uses and remove bellows 414.

As shown in Figure 9, dryer 100 also comprises conductive sensor 450 and the earth electrode 460 of the physical property for measuring laundry water.Conductive sensor 450 and earth electrode 460 project to the inside of heat-exchange tube 410.As mentioned above, the oven dry air containing Soft flocks or the laundry water containing Soft flocks flow in heat-exchange tube 410.The Soft flocks of drying in air or laundry water be easy to be deposited in project to heat-exchange tube 410 inside conductive sensor 450 and earth electrode 460 on.

Exhaust outlet 413 is opening (namely to roof 115 opening) upward.Filter 700 offsets to the direction (namely along the direction of back face wall 112) substantially vertical with the direction of exhaust outlet 413 opening, and therefore the sight line of operator arrives the inner face 411 of heat-exchange tube 410 by exhaust outlet 413.Therefore, the operator removed by bellows 414 can observe the inside of heat-exchange tube 410 via exhaust outlet 413, thus is easy to confirm whether Soft flocks are deposited on conductive sensor 450 and/or earth electrode 460.

(filter)

Figure 10 is the sectional view of the filter 700 be connected with bellows 414.Fig. 1, Fig. 8 and Figure 10 is utilized to be described filter 700.

The upside assembly 720 of the top of assembly 710 on the downside of filter 700 comprises downside assembly 710 and is arranged on.Downside assembly 710 is fixed in main basket 110 inside, and unlike this, upside assembly 720 can easily unload from main basket 110.The conduit tube component 660 be described relatively with Fig. 8 is arranged on the assembly 710 of downside.

Figure 11 is the sectional view of downside assembly 710.Figure 10 and Figure 11 is utilized to be described downside assembly 710.

Downside assembly 710 comprises the basket 730 for accommodating upside assembly 720.Basket 730 comprises: be formed with the right side wall 732 to the outstanding roughly cylindric inflow entrance 731 of bellows 414; And with right side wall 732 left side wall 733 in opposite directions.Dry air by bellows 414 and inflow entrance 731 in inflow filter 700.

Downside assembly 710 also comprises the lower filter portion 735 connecting right side wall 732 and left side wall 733.The inner space that basket 730 is formed is divided into space, the upside US and the lower side space LS adjacent with space, upside US that are communicated to inflow entrance 731 by lower filter portion 735.The lower side space LS be formed in below the space US of upside is arrived after the oven dry air inflow upside space US that inflow entrance 731 flows into.

As shown in Figure 10, collecting upside assembly 720 in the US of space, upside.Upside assembly 720 comprises upside filter house 725.Upside filter house 725 is adjacent to lower filter portion 735.In addition, upside filter house 725 is almost parallel with lower filter portion 735.

The oven dry air inflow flowed into from inflow entrance 731 is arranged in the upside assembly 720 in the space US of upside.The oven dry air flowed in the assembly 720 of upside flows along the first direction FD (namely along the direction of back face wall 112) towards left side wall 733.

Lower filter portion 735 is formed in the top of the coupling part of lower filter portion 735 and right side wall 732 with the coupling part of left side wall 733.Therefore, lower filter portion 735 and the upside filter house 725 parallel with lower filter portion 735, relative to the flow direction of the oven dry air of first direction FD tilt (in Fig. 10,0 ° of < θ < 90 ° (θ is the angle of inclination of upside filter house 725 relative to first direction FD)).

Lower filter portion 735 and upside filter house 725 remove Soft flocks from the oven dry air flowing to lower side space LS from space, upside US.As mentioned above, lower filter portion 735 and upside filter house 725 relative to the oven dry air of first direction FD the flow direction and tilt, therefore can guarantee the larger area for removing Soft flocks.

Figure 12 is the top view of the dryer 100 of removing upside assembly 720.Fig. 3, Figure 10 to Figure 12 cleaning method to lower filter portion 735 is utilized to be described.

As shown in figure 12, the conveying end 701 of opening is upward formed at the roof 115 of main basket 110.Upside assembly 720 inserts upside space US by conveying end 701 and is installed on main basket 110.When taking out upside assembly 720 by conveying end 701 from main basket 110, lower filter portion 735 will expose.

As mentioned above, lower filter portion 735 is connected to right side wall 732 and the left side wall 733 of filter 700, and therefore user easily observes lower filter portion 735 by conveying end 701.Therefore, user can easily find and remove the Soft flocks be deposited in lower filter portion 735.

Fig. 5, Fig. 6, Figure 10 and Figure 11 flowing to the oven dry air in filter 700 is utilized to be described.

As shown in Figure 10, flow from the oven dry air of inflow entrance 731 inflow upside space US along first direction FD (from right side wall 732 towards the direction of left side wall 733).Thereafter, dry air to flow to DD downward.

As shown in Figure 5, pipe assembly 660 extends from filter 700 to frontal.Therefore, flow into the oven dry air flow frontal (namely along the direction of left side wall 733) of lower side space LS and arrive pressure fan 610.In the following description, the flow direction of the oven dry air flowing to pressure fan 610 from filter 700 is called second direction SD.

Fig. 6 roughly represents the flowing of the oven dry air of first direction FD and second direction SD.As mentioned above, dry air and flow to first direction FD, thereafter DD flowing in downward direction.After this, dry air and be directed to the second direction SD substantially vertical with first direction FD by the basket 730 of downside assembly 710 and pipe assembly 660.The torsion of the flowing of this oven dry air occurs in upside filter house 725 and lower filter portion 735 around.Its result, around upside filter house 725 and lower filter portion 735, the flowing of drying air becomes complicated, thus the accumulation position easy change of Soft flocks on upside filter house 725 and lower filter portion 735.Because Soft flocks suitably disperse on upside filter house 725 and lower filter portion 735, therefore, the frequency of the clogging in upside filter house 725 and lower filter portion 735 reduces.

As shown in Figures 10 and 11, lower side space LS from the right side wall 732 of the basket 730 of downside assembly 710 left sidewall 733 expand gradually.As mentioned above, for the flowing reversing the oven dry air flowed, lower side space LS contributes to the pressure loss of reduction oven dry air being positioned at the expansion near the left side wall 733 of centrifugal direction.

(upside assembly)

Figure 13 is the stereogram of upside assembly 720.Figure 14 is the sectional view of upside assembly 720.Utilize Fig. 3, Figure 10, Figure 12 to Figure 14 be described upside assembly 720.

Upside assembly 720 not only comprises above-mentioned upside filter house 725, but also comprises with the mode that can unload from main basket 110 basket 740 formed and the lid 750 being arranged on the substantially rectangular shape basket 740.Basket 740 comprises the first basket 760 supporting upside filter house 725 and the second basket 770 rotatably supporting the first basket 760.Lid 750 is installed on the second basket 770.

As being described relatively with Figure 12, be formed with conveying end 701 at the roof 115 of main basket 110.As shown in Figure 3, lid 750 covers conveying end 701.

As shown in figure 13, the first basket 760 being roughly triangle box like comprises inclined plane 761.Inclined plane 761 is in clathrate.The filter screen used as upside filter house 725 is arranged in cancellate inclined plane 761.As being described relatively with Figure 10, inclined plane 761 is almost parallel with lower filter portion 735.

Figure 15 is the front view of upside assembly 720.Figure 13 and Figure 15 is utilized to be described upside assembly 720 further.

First basket 760 comprises rotation projection 762.Rotate the upper right side that projection 762 is formed in the first basket 760.Second basket 770 comprises the support tube 771 roughly mutually auxiliary with rotating projection 762.The rotation projection 762 being formed in the upper right side of the first basket 760 is inserted through support tube 771.Its result, the first basket 760 rotatably supports and is connected to the second basket 770.In the present embodiment, be formed at the first basket 760 and rotate projection 762, be formed with support tube 771 at the second basket 770.Replace, also can form support tube at the first basket, and form rotating shaft at the second basket.

Figure 16 is the right side view of the first basket 760.Figure 10, Figure 13 and Figure 16 is utilized to be described the first basket 760.

As shown in Figure 10, the first basket 760 is all housed in the space US of upside.As shown in figure 16, the first basket 760 comprises the right side wall 764 being formed with opening portion 763.Flowed in the first basket 760 through opening portion 763 by the oven dry air of inflow entrance 731.The upside filter house 725 be arranged in cancellate inclined plane 761 catches the Soft flocks of drying in air.

As shown in figure 13, when the left end that the first basket 760 is positioned at this first basket 760 is connected to the primary importance of the second basket 770, the first basket 760 and the cooperation of the second basket 770 form the receiving space for accommodating the Soft flocks of being caught by upside filter house 725.

Figure 17 is the general profile chart of the upside assembly 720 with the first basket 760 rotated to the right.Figure 13, Figure 16 and Figure 17 is utilized to be described the removing method removing Soft flocks from upside assembly 720.

When the first basket 760 rotates to the departure direction (being right side in fig. 17) that the left end of the first basket 760 leaves the second basket 770, the Soft flocks of being caught by upside filter house 725 can be removed.

Figure 18 is the outline elevation of the upside assembly 720 with the first basket 760 rotated to departure direction further.The rotation of Figure 15 to Figure 18 to the first basket 760 is utilized to be described.

First basket 760 can rotate to departure direction further around rotation projection 762.As shown in figure 15, significantly outstanding to the right lid 750 comprises right border 751.As shown in figure 18, right border 751 is contacted with the right side wall 764 to the first basket 760 of departure direction rotation and limits the rotation of the first basket 760.In the following description, the position of the first basket 760 being limited rotation by lid 750 is called the second place.

In Figure 18 with chain-dotted line show when removing lid 750 from the second basket 770 from the second basket 770 to greatest extent to departure direction rotate the first basket 760.As shown in figure 18, when removing lid 750 from the second basket 770, the first basket 760 can rotate to departure direction further from the second place.Second basket 770 is included in and the connecting portion 772 that uses in the connection of lid 750.Connecting portion 772 is given prominence to laterally.After removing lid 750 from the second basket 770, when the first basket 760 rotates to departure direction to greatest extent, the right side wall 764 of the first basket 760 is contacted with the connecting portion 772 of the second basket 770.

(syndeton of the first basket and the second basket)

Figure 19 represents the rotation projection 762 of the first basket 760.Figure 19 (a) is the right side view of the first basket 760.Figure 19 (b) is the partial elevation view of the rotation raised 762 outstanding to frontal, represents the end surface shape rotating projection 762.Figure 19 (c) is the partial rear view of the end surface shape representing the rotation projection 762 that rearwardly direction is given prominence to.Figure 19 is utilized to be described rotation projection 762.

Rotation projection 762 comprises first rotation raised 765 outstanding to frontal and rotates raised 766 with second of the opposition side being formed in the first rotation raised 765.Be formed as rotating with first raised 765 roughly coaxial to the first outstanding the second rotation raised 766 of opposite direction rotating raised 765.Second of substantial cylindrical shape rotates the section that projection 766 has circular.On the other hand, the first rotation projection 765 of D shape cutting process has non-circular profiles.

First side face rotating projection 765 of D shape cutting process comprises tabular surface 767.Tabular surface 767 comprises the first tabular surface 768 and is formed in second tabular surface 769 of opposition side of the first tabular surface 768.Second tabular surface 769 and the first tabular surface 768 almost parallel.First side face rotating projection 765 also comprises the arcuation face 781 between the first tabular surface 768 and the second tabular surface 769.

Figure 20 represents the support tube 771 of the second basket 770.Figure 20 (a) is the right side view of the second basket 770.Figure 20 (b) is the part sectioned view of the second basket 770 observed from the arrow A direction shown in Figure 20 (a), represents that insertion first rotates the support tube 771 of projection 765.Figure 20 (c) is the part sectioned view of the second basket 770 observed from the arrow B direction shown in Figure 20 (a), represents that insertion second rotates the support tube 771 of projection 766.Figure 19 and Figure 20 is utilized to be described support tube 771.

Support tube 771 comprises support first and rotates the first support tube 773 of projection 765 and support the second support tube 774 that second rotates projection 766.Support tube 771 comprises the inner face 775 contacted with rotation projection 762.When the first basket 760 rotates, the first arcuation face 781 rotating projection 765 is slidingly contacted at the inner face 775 of the first support tube 773.On the other hand, the first tabular surface 767 rotating projection 765 leaves the inner face 775 of the first support tube 773.Second side face rotating projection 766 is contacted with the inner face 775 of the second support tube 774 on the whole.

Second support tube 774 comprises and the first support tube 773 forward surface 776 in opposite directions.First support tube 773 comprise and forward surface 776 interval first apart from the Part I 777 of D1 and and the Part II 778 of forward surface 776 interval second distance D2.In addition, second distance D2 is longer than the first distance D1.

Part I 777 comprises the edge 779 that regulation is formed in the borderline space part G between Part I 777 and Part II 778.Space part G is to rotate the rotating shaft RX of projection 762 for benchmark is towards radial direction opening.

Figure 21 represents the first basket 760 being installed on the second basket 770.Figure 22 represents the first rotation projection 765 of the first support tube 773 of the second basket 770 shown in Figure 21 and the first basket 760 shown in Figure 21.Figure 18, Figure 20 to Figure 22 connection to the first basket 760 and the second basket 770 is utilized to be described.

The position of rotation of the first basket 760 shown in Figure 21 corresponds to the position of the first basket 760 represented with chain-dotted line in Figure 18.The position of rotation of the first basket 760 shown in Figure 21, the first basket 760 is connected to the second basket 770.After the first basket 760 is connected to the second basket 770, the second basket 770 installs lid 750.In the following description, the position of rotation of the first basket 760 shown in Figure 21 is called installation site.

As being described relatively with Figure 18, lid 750 hinders the first basket 760 to rotate to installation site.Therefore, only otherwise remove lid 750 from the second basket 770, the connection of the first basket 760 and the second basket 770 can just be maintained.

As shown in figure 22, the edge 779 of void portion G comprises the edge, downside 783 on the upper edge part 782 of the boundary of void portion G and the border, downside of void portion G.Distance between upper edge part 782 and edge, downside 783 is defined as the distance be substantially equal between the first tabular surface 768 of the first rotation projection 765 and the second tabular surface 769.When the first basket 760 arrives installation site, tabular surface 767 is substantially vertical with the boundary face B be prescribed as the face by upper edge part 782 and edge, downside 783.

Distance between first tabular surface 768 and the second tabular surface 769 rotates in the section size of projection 765 the shortest first.Therefore, when the first basket 760 is positioned at other positions beyond installation site, edge 779 hinders the first rotation projection 765 to insert the first support tube 773 or unloads the first rotation projection 765 from the first support tube 773.On the other hand, when the first basket 760 arrives installation site, first rotates projection 765 inserts the first support tube 773 by space part G, or the first rotation projection 765 is departed from by space part G and the first support tube 773.

In the present embodiment, second rotates projection 766 and has and rotate the different section shape of projection 765 from first.Replace, second rotates projection also can have the section rotating projection same shape with first.In addition, the second support tube 774 has the shape different from the first support tube 773.Replace, the second support tube also can form image shape relative to the first support tube.

(heat radiation from filter)

Figure 23 is the general profile chart of the second basket 770.Figure 23 is utilized to be described the second basket 770.

Second basket 770 comprise horizontal traverse diapire 791, from the extended upward perisporium 792 of diapire 791 and the rib 793 that is formed in above diapire 791.Second basket 770 disk-shaped shape on the whole, diapire 791 and perisporium 792 form the recessed region of the depression relative to lid 750.The rib 793 be formed in above diapire 791 extends above perisporium 792.

Figure 24 is the stereogram of upside assembly 720.Fig. 1, Figure 12, Figure 23 and Figure 24 is utilized to be described upside assembly 720.

As shown in figure 24, the first basket 760, second basket 770 and lid 750 link together and integrally turn to upside assembly 720.As being described relatively with Figure 12, lid 750 covers the conveying end 701 on the roof 115 being formed in main basket 110 partly.

The lid 750 be arranged on the second basket 770 also covers the recessed region of the diapire 791 by the second basket 770 and perisporium 792 defined partly.Lid 750 is formed opening portion 754.Lid 750 comprises: have expose from main basket 110 outside (above) mainboard 752; And project to by the diapire 791 of the second basket 770 and the handle wall 753 in the recessed region of perisporium 792 defined.Handle wall 753 projects to relative to main basket 110 recessed recessed region from the edge of opening portion 754.

Figure 25 represents upside assembly 720.Figure 25 (a) is the top view of upside assembly 720.Figure 25 (b) is the sectional view along the C-C line shown in Figure 25 (a).Fig. 5 and Figure 25 is utilized to be described the heat radiation from upside assembly 720.

As being described relatively with Fig. 5, drying air and heated by heater 620.As shown in Figure 25 (b), the diapire 791 of the second basket 770 and perisporium 792 separate between the first basket 760 and lid 750.In addition, diapire 791 and perisporium 792 cooperate with the first basket 760 receiving space formed for accommodating Soft flocks.The oven dry air that heater via 620 heats flows into receiving space as Suo Shi the arrow of Figure 25 (b).

Because of the heat transfer from oven dry air, diapire 791 and perisporium 792 are heated.The opening portion 754 of lid 750 and be formed in lid 750 diapire 791 in opposite directions and perisporium 792 above rib 793 promote to dispel the heat from diapire 791 and perisporium 792.Therefore, diapire 791 and perisporium 792 excessive temperature rise can be suppressed.

Finger can insert in the opening portion 754 of lid 750 and remove upside assembly 720 from main basket 110 by user.As mentioned above, owing to can suppress diapire 791 and perisporium 792 excessive temperature rise, even if therefore the finger contact of user is in diapire 791 or perisporium 792, user also can not feel overheated.Therefore, the dryer 100 with higher security can be provided.

(heat exchanger)

Fig. 5 and Fig. 9 is again utilized to be described heat exchanger 400.

As shown in Figure 5, heat exchanger 400 is connected to tank 210.Therefore, such as, in laundry operation, laundry water is flowed in heat-exchange tube 410 by inflow entrance 412.

As shown in Figure 9, the second housing body 440 of heat exchanger 400 is provided with conductive sensor 450.Conductive sensor 450 is for detecting the foaming degree of the laundry water flowed in heat-exchange tube 410.For the detection method of the foaming degree of use conductive sensor 450, also known method can be applied.In addition, conductive sensor 450 also can be used to measure other physical property of laundry water.

In the present embodiment, conductive sensor 450 comprises first electrode 451 in the roughly centre position being arranged on heat-exchange tube 410 and is arranged on second electrode 452 of top of the first electrode 451.Conductive sensor 450 such as measures the impedance of laundry water between the first electrode 451 and the second electrode 452.First electrode 451 and the second electrode 452 are given prominence to from the inner face 411 of heat-exchange tube 410 for measuring the physical property of laundry water.Therefore, the first electrode 451 and the second electrode 452 are easy to tangle Soft flocks.The technology of supply described later and direct dehumidified water promotes to remove the Soft flocks of being caught by the first electrode 451 and the second electrode 452.

Figure 26 is the skeleton diagram of heat exchanger 400.The central figure of Figure 26 is the side view diagrammatically representing heat exchanger 400.The left figure of Figure 26 is the skeleton diagram of the inner face structure (i.e. the inner face structure of the first shell body 430) of the heat exchanger 400 observed from the A-A direction Figure 26.The right figure of Figure 26 is the skeleton diagram of the inner face structure (i.e. the inner face structure of second housing body 440) of the heat exchanger 400 observed from the B-B direction Figure 26.Figure 27 is the approximate three-dimensional map of second housing body 440.Fig. 4, Fig. 8, Figure 26 and Figure 27 is utilized to further illustrate heat exchanger 400.

First shell body 430 comprises the edge surface 431 utilizing such as ultrasonic wave to be connected to second housing body 440.Similarly, second housing body 440 comprises the edge surface 441 of the edge surface 431 being connected to the first shell body 430.Edge surface 431 and edge surface 441 overlap, carried out welding thereafter, thus formed heat-exchange tube 410.

As being described relatively with Fig. 4, dehumidifying water is supplied to the first feed water inlet 421 and the second feed water inlet 422 from the adjutage 321 for water assembly 300.In addition, as being described relatively with Fig. 8, dew is supplied to the 3rd feed water inlet 423 by the tube connector 662 extended from pipe assembly 660 as dehumidifying water.

Second housing body 440 comprises the water storage wall 442 of encirclement first feed water inlet 421, temporarily to store the dehumidifying water flowed into from the first feed water inlet 421.First shell body 430 comprises and utilizes such as ultrasonic wave to be welded in water storage wall 432 on the water storage wall 442 of second housing body 440.Weld water storage wall 442 and water storage wall 432, thus form the water storage room for storing the dehumidifying water flowed into from the first feed water inlet 421.

As shown in figure 27, the water storage wall 442 of second housing body 440 is formed with notch part 443.The dehumidifying water be stored in the water storage room formed by water storage wall 442,432 is flowed down by the inner face 411 of notch part 443 along second housing body 440.The water storage wall 432 of the first shell body 430 is also formed identical notch part (not shown).Be stored in dehumidifying water in the water storage room formed by water storage wall 442,432 to flow down along the inner face 411 of the first shell body 430 by being formed in the notch part on water storage wall 432.

Second feed water inlet 422 and the 3rd feed water inlet 423 make dehumidifying water flow in heat-exchange tube 410 from the top of the second electrode 452 near the base end part being arranged on exhaust outlet 413.Therefore, the roughly whole inner face 411 of heat-exchange tube 410 is used to dehumidify to oven dry air.

First shell body 430 and second housing body 440 also comprise the dividing plate 444 of the stream separating the oven dry air specified by heat-exchange tube 410 partly.The dividing plate 444 of the first shell body 430 and second housing body 440 utilizes such as ultrasonic wave and welded.The result of welding forms the water storage room for storing the dehumidifying water flowed into from the second feed water inlet 422 and the 3rd feed water inlet 423.The dividing plate 444 extended substantially horizontally between the second feed water inlet 422 (and the 3rd feed water inlet 423) and the second electrode 452 temporarily stores the water that dehumidifies above the second electrode 452.

As shown in figure 27, dividing plate 444 is formed with opening portion 445.The dehumidifying water be stored in the water storage room formed by dividing plate 444 is flowed down by the inner face 411 of opening portion 445 along second housing body 440.The dividing plate 444 of the first shell body 430 is also formed identical opening portion (not shown).Be stored in dehumidifying water in the water storage room formed by dividing plate 444 to flow down along the inner face 411 of the first shell body 430 by being formed in the opening portion 445 on dividing plate 444.

Heat exchanger 400 comprises the diffusion rib 470 that the dehumidifying water that makes to flow down along inner face 411 substantially horizontally spreads.Diffusion rib 470 is given prominence to from inner face 411 in the below of the first feed water inlet 421.Therefore, the dehumidifying water entirety diffusion that rib 470 can will be supplied from the first feed water inlet 422, feed water inlet 421, second and the 3rd feed water inlet 423 is spread.In the present embodiment, spreading rib 470 makes dehumidifying water substantially horizontally spread.Replace, diffusion rib also can make any direction that dehumidifying water intersects to the flow direction with oven dry air spread.

Heat-exchange tube 410 comprises the first side wall 425 and the first side wall 425 the second sidewall 426 in opposite directions and the main wall 427 between the first side wall 425 and the second sidewall 426 that are formed with the first feed water inlet 421 and the second feed water inlet 422.Diffusion rib 470 comprises the first rib 471 extended from the first side wall 425 along main wall 427 to the second sidewall 426 and the second rib 472 extended along main wall 427 to the first side wall 425 from the second sidewall 426.First rib 471 and second rib 472 roughly alternately arrange along the length direction of heat-exchange tube 410.

Water storage wall 442,432 forms the water storage room storing the water that dehumidifies together with the first side wall 425.First rib 471 comprises the base end part 473 of dehumidifying water of water storage room and the leading section 474 of the opposition side of base end part 473 that receive free water storage wall 442,432 and the first side wall 425 formation.Leading section 474 is more positioned at below than base end part 473.Therefore, the dehumidifying water arriving first rib 471 flows to leading section 474 from base end part 473.Accordingly, the water that dehumidifies spreads in the horizontal direction.In addition, the base end part 473 being formed in the first rib 471 immediately below the water storage room formed by water storage wall 442,432 and the first side wall 425 receives the dehumidifying water comparing volume.Therefore, the base end part 473 of first rib 471 it is preferable that the side rib 475 comprising the inner face 411 along the first side wall 425 and substantially horizontally extend.

Second rib 472 comprises the leading section 477 being adjacent to the base end part 476 of the second sidewall 426 and the opposition side of base end part 476.Leading section 477 is more positioned at below than base end part 476.Therefore, the dehumidifying water arriving second rib 472 flows to leading section 477 from base end part 476.Accordingly, the water that dehumidifies spreads in the horizontal direction.

In the present embodiment, second rib 472 receives the dehumidifying water flowed down from the first rib 471 of the top.In addition, the first rib 471 of bottom receives the dehumidifying water flowed down from second rib 472.

Figure 28 (a) is the enlarged drawing of the first rib 471 of the top.Figure 28 (b) is the general profile chart of second housing body 440.Figure 26 to Figure 28 (b) is utilized to be described diffusion rib 470.

As shown in figure 27, between base end part 473,476 and leading section 474,477, diffusion rib 470 is formed with groove portion 478.

The flowing of the dehumidifying water flowed down along inner face 411 is roughly illustrated in Figure 26 and Figure 28 (a).As mentioned above, the dehumidifying current direction leading section 474,477 of diffusion rib 470 is arrived.Groove portion 478 allows a part for the dehumidifying water flowing to leading section 474,477 to flow down.Accordingly, the water that dehumidifies spreads on the whole inner face 411 of main wall 427.

As shown in Figure 27 and Figure 28 (b), diffusion rib 470 is in taper, and therefore base end part 473,476 is greater than the overhang of leading section 474,477 from the overhang of the inner face 411 of main wall 427.As mentioned above, the part flowing to the dehumidifying water of leading section 474,477 is flowed down by groove portion 478, and the amount therefore spreading the dehumidifying water that rib 470 flatly guides reduces gradually along with towards leading section 474,477.Therefore, even if be the diffusion rib 470 of taper, the horizontal proliferation function to dehumidifying water also can be given full play to.In addition, the minimizing towards the overhang of leading section 474,477 can not apply unnecessary resistance to the flowing of drying air.Therefore, the cycle efficieny of drying air not easily reduces.

As shown in figure 26, dry air flow into from inflow entrance 412 and discharge from the exhaust outlet 413 of top.As shown in figure 27, spreading rib 470 comprises with along with upward and overhang becomes the inclined plane 479 of the general planar that large mode tilts gradually.Therefore, spread rib 470 and invalidly can not apply larger resistance to drying air.Therefore, the cycle efficieny of drying air not easily reduces.

As shown in figure 26, heat-exchange tube 410 forms the stream from inflow entrance 412 to exhaust outlet 413 in bowing.The diffusion rib 470 be formed on the first shell body 430 is positioned at centripetal side on bending stream.In addition, the diffusion rib 470 be formed on second housing body 440 is positioned at centrifugal side.Therefore, in the following description, the diffusion rib 470 be formed on the first shell body 430 can be called centripetal rib 481 as required.In addition, the diffusion rib 470 be formed on second housing body 440 can be called centrifugal rib 482 as required.

Horizontal line HL, centripetal rib 481 is illustrated relative to the tilt angle theta 1 of horizontal line HL and centrifugal rib 482 tilt angle theta 2 relative to horizontal line HL in Figure 26.As shown in figure 26, the tilt angle theta 2 of centrifugal rib 482 is less than the tilt angle theta 1 of centripetal rib 481.Therefore, the flow velocity of the dehumidifying water flowed down along the inner face 411 of second housing body 440 is less than the flow velocity of the dehumidifying water that the inner face 411 along the first shell body 430 flows down.

Oven dry air is greater than the flow velocity of oven dry air along the inner face 411 of the first shell body 430 of centripetal side along the flow velocity of the inner face 411 of the second housing body 440 of centrifugal side.As mentioned above, the flow velocity of the dehumidifying water that the inner face 411 along second housing body 440 flows down is slow, therefore can dry air faster with flow velocity and suitably carry out heat exchange.And, due to the dehumidifying water that flows down along the inner face 411 of second housing body 440 and along the inner face 411 of second housing body 440 oven dry air between relative velocity reduce, thus dehumidifying water is not easily rolled-up.

Figure 29 is the outline elevation of second housing body 440.Fig. 7, Figure 26, Figure 27 and Figure 29 cleaning to conductive sensor 450 is utilized to be described.

As shown in figure 27, the main wall 427 of second housing body 440 is formed with the opening portion 453 for inserting conductive sensor 450.As shown in Fig. 7 and Figure 27, second housing body 440 comprises to the inside outstanding stationary magazine creel 455, to screw togather with for conductive sensor 450 being fixed on the fixtures 454 (with reference to Fig. 7) such as screw on second housing body 440.In the present embodiment, between a pair stationary magazine creel 455, opening portion 453 is formed with.

As shown in figure 29, the leading section 477 of second rib 472 is formed in directly over the first electrode 451 (on plumb line).Therefore, to be guided by second rib 472 and the dehumidifying water arriving leading section 477 flow on the first electrode 451.Accordingly, the Soft flocks be attached on the first electrode 451 are suitably removed.Replace, also can form the groove portion of diffusion rib directly over conductive sensor.The dehumidifying water flowed down by groove portion is directly contacted with conductive sensor, and therefore Soft flocks are suitably removed.

2 first ribs 471 are formed above second rib 472.The groove portion 478 be formed on the first rib 471 of the top is positioned at directly over time leading section 474 of the first rib 471 of top.Therefore, the flow velocity of the dehumidifying water that the first rib 471 via secondary top flows down increases, and therefore this dehumidifying water is also easy to collide the first electrode 451.

Figure 30 is the outline longitudinal section of heat exchanger 400.The flowing of Figure 30 to the dehumidifying water flowed down from dividing plate 444 is utilized to be described.

As mentioned above, dividing plate 444 is formed and is used for temporarily storing the water storage room being supplied to the dehumidifying water of the second feed water inlet 422 (and the 3rd feed water inlet 423).The water storage room formed by dividing plate 444 is along the Directional Extension crossing the flow direction of drying air, and the water that therefore dehumidifies is supplied to the inner face 411 of heat exchanger 400 in a big way.

Figure 31 is that the outline on the top of heat exchanger 400 amplifies longitudinal section.Figure 32 is the outline sectional elevation on the top of heat exchanger 400.Utilize Fig. 4, Fig. 5, Figure 29 to Figure 32 be described dividing plate 444.

As mentioned above, heat exchanger 400 comprises the first shell body 430 and the second housing body 440 overlapping with the first shell body 430.Dividing plate 444 comprises the first dividing plate 446 be formed on the first shell body 430 and the second partition 447 be formed on second housing body 440.

As shown in figure 32, the first dividing plate 446 comprises and second partition 447 the first edge 448 in opposite directions.Second partition 447 comprises the second edge 449 being connected to the first edge 448.In the present embodiment, the first edge 448 and the second edge 449 utilize ultrasonic wave and are engaged.Accordingly, dividing plate 444 forms the water storage room across the first shell body 430 and second housing body 440.

As shown in Figure 30 and Figure 31, dividing plate 444 is formed with multiple opening portion 445.Dehumidifying water is discharged from the water storage room that dividing plate 444 is formed by opening portion 445.

Figure 32 roughly illustrates the configuration of the opening portion 445 be formed on dividing plate 444.Figure 32 show also the section of exhaust outlet 413.A part for exhaust outlet 413 is used as dividing plate 444.The tube wall of exhaust outlet 413 is formed pair of openings portion 445.As shown in figure 30, the dehumidifying water flowed out from these opening portions 445 flows mostly to the inner face 411 of the main wall 427 of the first shell body 430.

As shown in figure 32, second partition 447 is formed with 4 opening portions 445 that the inner face 411 along the main wall 427 of second housing body 440 arranges.As shown in figure 30, the dehumidifying water flowed out from these opening portions 445 mainly flows along the inner face 411 of the main wall 427 of second housing body 440.

As shown in figure 32, notch part is formed with at the first two ends, edge 448 of the first dividing plate 446.When connection first edge 448 and the second edge 449, form the opening portion 445 adjoined with the first side wall 425 and second sidewall 426 of heat exchanger 400 respectively.These opening portions 445 borderline being formed in the first edge 448 and the second edge 449 allow to dehumidify water along heat exchanger 400 sidewall (the first side wall 425 and the second sidewall 426) and flow down.

As shown in figure 29, the inner face 411 of the second electrode 452 from the main wall 427 of second housing body 440 between the first rib 471 and dividing plate 444 of the top is given prominence to.One in the opening portion 445 that the inner face 411 of the main wall 427 of second housing body 440 arranges is formed on the plumb line VL of the second electrode 452.Therefore, from directly over the dehumidifying water that flows down of opening portion 445 directly clean the second electrode 452, suitably remove Soft flocks.

As mentioned above, control device 250 controls for water assembly 300, during oven dry air flows in heat-exchange tube 410, supplies dehumidifying water by the first feed water inlet 421 and 422 pairs, the second feed water inlet heat exchanger 400.Also as required, for water assembly 300 under the control of control device 250, also in the laundry operation of supplying laundry water to treatment trough 200, dehumidifying water can be supplied to heat exchanger 400.

Conductive sensor 450 exports the data relevant to the physical property of laundry water to control device 250, and therefore, control device 250 also can control based on the physical data of laundry water for water assembly 300.Such as, if the physical data display Soft flocks of laundry water are attached to the first electrode 451 and/or the second electrode 452, then, after control device 250 also can reduce the liquid level in heat exchanger 400 opening draining valve 361, dehumidifying water is supplied to heat exchanger 400.

(ground structure)

The ground structure of Fig. 5 and Figure 29 to dryer 100 is utilized to be described.

Dryer 100 utilizes power operation.Therefore, from the view point of security, dryer 100 comprises earth connection 101.In the present embodiment, earth connection 101 extends from CD-ROM drive motor 230 and is suitably carried out grounding.

As shown in figure 29, earth electrode 460 is arranged on the below of feed water inlet 420, and projects in stream that heat-exchange tube 410 formed.Earth electrode 460 is arranged on the lower end of the stream that heat-exchange tube 410 is formed, and is therefore contacted with the dehumidifying water flowed down from feed water inlet 420 and the laundry water both sides flowed into from inflow entrance 412.Earth electrode 460 is electrically connected on earth connection 101.

In utilize the conductive sensor 450 of work about electric power to project to stream that heat-exchange tube 410 formed, it is contacted with laundry water or dehumidifying water, earth electrode 460 is directly contacted with the water in heat-exchange tube 410 afterwards, therefore directly can carry out grounding to the water in heat-exchange tube 410.Therefore, the security of dryer 100 improves.

Figure 33 is the outline enlarged drawing of the bottom of second housing body 440.Fig. 5, Figure 29 and Figure 33 is utilized to be described ground structure further.

The water storage region 461 surrounding earth electrode 460 is formed at the inner face 411 of second housing body 440.Water storage region 461 is relative to the inner face 411 of second housing body 440 and recessed setting.Therefore, the dehumidifying water flowed down from feed water inlet 420 and from inflow entrance 412 flow into laundry water be stored in water storage region 461.Earth electrode 460 protrudes from water storage region 461, therefore suitably contacts with dehumidifying water and laundry water.

Second housing body 440 comprises from the outstanding guiding rib 462 of the inner face 411 of second housing body 440, to guide the dehumidifying water flowed down from feed water inlet 420 to water storage region 461.Guiding rib 462 comprises the first guiding rib 463 of directly receiving the dehumidifying water flowed down from the first rib 471 of bottom and receives crosses the first guiding rib 463 and the second guiding rib 464 of dehumidifying water of flowing down.Accordingly, the water that dehumidifies suitably is contacted with earth electrode 460.

Figure 34 is the outline amplification view of the syndeton between tank 210 and heat exchanger 400.Fig. 5, Fig. 7, Figure 26, Figure 29 and Figure 34 is utilized to be described ground structure further.

As being described relatively with Fig. 7, the top rear face of second housing body 440 along main basket 110 back face wall 112 and formed.As shown in Fig. 7 and Figure 34, the bottom of heat exchanger 400 bends to frontal.Its result, inflow entrance 412 is connected to tank 210.

The inner face 411 being formed with the second housing body 440 in water storage region 461 bends slightly toward below.In addition, water storage region 461 recessed setting relative to inner face 411.Therefore, dehumidifying water and laundry water are easy to be stored in water storage region 461.The water be stored in water storage region 461 is illustrated in Figure 34.

As shown in figure 34, earth electrode 460 protrudes from water storage region 461.Therefore, earth electrode 460 is suitably contacted with the water be stored in water storage region 461.

As shown in figure 34, water storage region 461 and inflow entrance 412 are in opposite directions.Therefore, when discharging dehumidifying water or laundry water by water discharge outlet 362, the water contacted with the conductive sensor 450 in heat exchanger 400, after being contacted with earth electrode 460, is discharged from heat exchanger 400 via inflow entrance 412.Therefore, the water being appropriately grounding is discharged from dryer 100.Accordingly, the security of dryer 100 improves.

(drainage system)

Utilize Fig. 4, Fig. 5 and Figure 34 to for discharging laundry water for doing washing and for being described with the drainage system of drying air and carry out the dehumidifying water of heat exchange outside main basket 110.

As mentioned above, the water having been carried out grounding by earth electrode 460 is flowed out from inflow entrance 412 when draining valve 361 is opened, and arrives drainpipe 360 thereafter by connecting drainpipe 360 with the tank 210 of heat exchanger 400.In the present embodiment, tank 210 is exemplified as attaching parts.

As shown in Figure 5, dryer 100 comprises the sensing element 800 of the dryness fraction of the clothing in measurement processing groove 200.Sensing element 800 comprises the first temperature sensor 805 be arranged on after heater 620 and the second temperature sensor 810 be arranged on filter assemblies 500.The temperature of the oven dry air carried out before clothes drying measured by first temperature sensor 805.The temperature of the dehumidifying water being flowed into filter assemblies 500 by tank 210 measured by second temperature sensor 810.The oven dry degree of clothing is estimated according to the difference of the temperature measured by sensing element 800.About the method detecting dryness fraction based on temperature difference, applicable known method.In the present embodiment, the second temperature sensor 810 is exemplified as temperature sensor.

As being described relatively with Fig. 4 and Fig. 5, the vibration caused by treatment trough 200 is appropriately attenuated by damping means 240 and sprung parts 245.Therefore, the face wall 111 being fixed with filter assemblies 500 is vibrated hardly.Therefore, the structure for fixing the second temperature sensor 810 becomes simple.

Figure 35 is the outline right side view of filter assemblies 500.Figure 36 is the general profile chart of the filter assemblies 500 along the A-A line shown in Figure 35.Utilize Fig. 4, Fig. 5, Figure 35 and Figure 36 that the mounting structure of the second temperature sensor 810 pairs of filter assemblies 500 is described.

As shown in Figures 4 and 5, drainpipe 360 comprises the tube connector 363 connecting filter assemblies 500 and tank 210.As shown in Figure 5, draining valve 361 is arranged on tube connector 363.

As shown in Figure 35 and Figure 36, filter assemblies 500 comprises the connecting cylinder 520 chimeric with tube connector 363.As shown in figure 36, connecting cylinder 520 comprises the tube wall 525 with the regulation dehumidifying internal face 521 on draining road of water flow and the outside wall surface 522 of the opposition side of internal face 521.The heat flowing into the dehumidifying water of connecting cylinder 520 is passed to outside wall surface 522.

Second temperature sensor 810 comprises the measuring cell 811 of the generation voltage signal (hereinafter referred to as temperature signal) corresponding with the heat being passed to outside wall surface 522 and transmits the holding wire 812 from the temperature signal of measuring cell 811 to control device 250.Measuring cell 811 is pushed on outside wall surface 522 and suitably measures the temperature of dehumidifying water.The holding wire 812 being connected to measuring cell 811 transmits temperature signal to control device 250, thus control device 250 can the dryness fraction of clothing in determination processing groove 200.Control device 250 adjusts the rotating speed of such as fan 611 according to the dryness fraction of clothing.Control device 250 replaces this and/or additional the supply adjusting the dehumidifying water of heat exchanger 400.

Filter assemblies 500 also comprises the receiving cartridge 512 of collecting filter element 510.Soft flocks contained in the dehumidifying water (and the laundry water for doing washing) clean heat exchanger 400 or other foreign matters are suitably removed by the filter element 510 in receiving cartridge 512.In the present embodiment, filter element 510 is exemplified as filter element.

Connecting cylinder 520 comprises the base end part 513 being connected to receiving cartridge 512 and the holding cylinder 514 of giving prominence to from the outside wall surface 522 of base end part 513.Holding cylinder 514 is surrounded and is kept measuring cell 811.

Connecting cylinder 520 also comprises from the upright installation rib 515 of outside wall surface 522.Holding wire 812 uses suitable fixture 516 to be fixed on and installs on rib 515.In the interval till fixture 516 to measuring cell 811, holding wire 812 is to push the mode elastic deformation of measuring cell 811 to outside wall surface 522.Holding cylinder 514 is formed the slit 517 formed in the mode of the suitably elastic deformation of inhibit signal line 812.Holding wire 812 is inserted in slit 517.

Filter assemblies 500 is fixed on stabilized front wall 111, and the syndeton therefore between the second temperature sensor 810 and filter assemblies 500 becomes simple.In addition, as shown in Figure 4, filter assemblies 500 is adjacent to control device 250, and therefore connecting measuring cell 811 also can be shorter with the holding wire 812 of control device 250.Therefore, without the need to the relay point for transmitting temperature signal.Accordingly, the equipment of the dryness fraction for measuring clothing can cheap be constructed.And that can carry out efficiently arranging the second temperature sensor 810 to dryer 100 arranges operation and the upkeep operation relevant to the second temperature sensor 810.

Figure 37 is the curve map roughly representing the installation site of temperature sensor and the relation of detection sensitivity.Fig. 5, Figure 35 to Figure 37 is utilized to be described the installation site of temperature sensor and the relation of detection sensitivity.

As being described relatively with Figure 35 and Figure 36, the second temperature sensor 810 of present embodiment is arranged on the filter assemblies 500 that is separated with heat exchanger 400.Its result, the second temperature sensor 810 is arranged in main basket 110 with simple mounting structure.On the other hand, the second temperature sensor 810 and heat exchanger 400 separate and will likely cause the detection sensitivity of temperature to reduce, and the present inventors have studied the impact that the second temperature sensor 810 separates with heat exchanger 400.

The present inventors have carried out 2 times and have measured.In measuring first, as being described relatively with Figure 35 and Figure 36, temperature sensor is arranged on temperature filter assemblies being measured dehumidifying water by the present inventors.In measuring second, temperature sensor is arranged on (i.e. the connecting portion of tube connector 363 and tank 210) near tank for measuring the temperature of the dehumidifying water after just discharging from heat exchanger.

" warming up period " shown in Figure 37 is for during baking operation just started rear appearance, and during this period, the temperature of dehumidifying water has the tendency of increase.The temperature of the dehumidifying water in warming up period rises and represents that the oven dry of clothing is in progress rapidly.

After " the permanent rate phase " shown in Figure 37 appear at " warming up period ", during this period, the temperature of dehumidifying water remains on constant.The variations in temperature of the constant in " permanent rate phase " represents that the oven dry of clothing is carried out.

After " the lapse rate phase " shown in Figure 37 appear at " permanent rate phase ", during this period, the temperature of dehumidifying water presents the tendency of reduction.The temperature reduction of the dehumidifying water in " lapse rate phase " represents that the oven dry of clothing has been tending towards roughly completing.

As shown in figure 37, the tendency of the variations in temperature of dehumidifying water when shifting from " permanent rate phase " to " lapse rate phase " and opportunity are roughly the same first measures and second measures.This means that the second temperature sensor 810 be arranged on filter assemblies 500 can dehumidify with the sensitivity technique roughly the same with the sensor be arranged near tank 210 variations in temperature of water.Therefore, control device 250 suitably can judge the dryness fraction of clothing based on the temperature signal from the second temperature sensor 810 be arranged on filter assemblies 500.

Above-mentioned embodiment mainly comprises the device for clothing processing with following structure.Be kept for while there is the device for clothing processing Absorbable organic halogens of following structure the sensing element of the dryness fraction measuring clothing.

Device for clothing processing involved in the present invention, comprising: treatment trough, for accommodating clothing; Drive source, drives described treatment trough; Main basket, accommodates described treatment trough and described drive source; Support component, supports described treatment trough and decay to be passed to the vibration of described main basket from described treatment trough; Drainage system, discharges the laundry water for the described clothing washed or in treatment trough described in rinsing outside described main basket; And the circulatory system, make the oven dry air circulation of the described clothing in the described treatment trough of oven dry, wherein, the described circulatory system comprises the sensing element of the dehumidifying section dehumidified to described oven dry air and the dryness fraction measuring described clothing, and described dehumidifying section comprises: the guiding tube comprising the inner face of the stream of the described oven dry air flowing of regulation; And for supplying the feed water inlet be applied to the dehumidifying water that described oven dry air dehumidifies in described stream, wherein, described guiding tube comprises the inflow entrance that the described laundry water that is supplied to described treatment trough and described oven dry air flow into, and described drainage system comprises: the drainpipe guiding described laundry water outside described main basket; And connect the attaching parts of described inflow entrance and described drainpipe, wherein, described drainpipe comprises the fixed part being fixed in described main basket, and described sensing element is comprised for measuring the temperature sensor being flowed into the temperature of the described dehumidifying water in described fixed part by described attaching parts.

According to described structure, drive source drives the treatment trough of collecting clothing.Main basket collecting treatment trough and drive source.The support component supporting treatment trough makes the vibration attenuation being passed to main basket from treatment trough.Therefore, the vibration produced because of the driving for the treatment of trough is passed to main basket hardly.

The laundry water of the clothing be used in carrying out washing treatment groove discharged by drainage system outside main basket.The circulatory system of the oven dry air circulation of the clothing in drying and processing groove is comprised drying the dehumidifying section that dehumidifies of air and the sensing element for the dryness fraction of measuring clothing.Dehumidifying section comprises and has regulation and dry the guiding tube of the inner face of the stream of air flowing and will be used for being supplied to feed water inlet in stream to drying the dehumidifying water that dehumidifies of air.Drainage system comprises the drainpipe guiding laundry water outside main basket and the attaching parts connecting inflow entrance and drainpipe.Drainpipe comprises the fixed part being fixed in main basket.As mentioned above, the vibration produced because of the driving for the treatment of trough is passed to main basket hardly, and therefore fixed part is also stably kept by main basket.Sensing element comprises the temperature sensor for measuring the temperature being flowed into the dehumidifying water in fixed part by attaching parts.Therefore, for measuring the temperature of dehumidifying water with measuring the temperature sensor Absorbable organic halogens of the dryness fraction of clothing.

In said structure, it is preferable that, described temperature sensor comprises: contact with described fixed part thus measure the measuring cell of the temperature of described fixed part: and the holding wire be connected with described measuring cell, described fixed part keeps described holding wire, and described holding wire is to push the mode elastic deformation of described measuring cell to described fixed part.

According to described structure, temperature sensor comprises and to contact with fixed part thus measure the measuring cell of the temperature of fixed part and be connected to the holding wire of measuring cell.Fixed part keeps with the holding wire of the mode elastic deformation to fixed part pushing measuring cell.Measuring cell stably contacts with fixed part, therefore for measuring the temperature of dehumidifying water with measuring the temperature sensor Absorbable organic halogens of the dryness fraction of clothing.

In said structure, it is preferable that, described fixed part comprises tube wall, and described tube wall comprises: the internal face specifying the draining road of described dehumidifying water flow; And by the outside wall surface that described measuring cell pushes, the temperature of the described dehumidifying water transmitted by described tube wall measured by described measuring cell.

According to described structure, the tube wall of fixed part comprises the internal face on draining road and the outside wall surface of measured element forces of regulation dehumidifying water flow.The temperature of the dehumidifying water transmitted to the measuring cell measurement that outside wall surface is pushed by tube wall by the holding wire of elastic deformation, therefore for measuring the temperature of dehumidifying water with measuring the temperature sensor Absorbable organic halogens of the dryness fraction of clothing.

In said structure, it is preferable that, described fixed part comprises and protrudes from described outside wall surface and the holding cylinder keeping described measuring cell, wherein, forms the slit for inserting described holding wire in described holding cylinder.

According to described structure, the holding cylinder of fixed part is given prominence to from outside wall surface and keeps measuring cell.Holding cylinder is formed with the slit for inserting holding wire, therefore temperature sensor is suitably maintained by simple holding structure.

In said structure, it is preferable that, described fixed part comprises the filter element removing Soft flocks from the laundry water by described drainage system.

According to described structure, for keeping the fixed part of temperature sensor to remove Soft flocks from laundry water, therefore discharge the laundry water containing a small amount of Soft flocks from main basket.

Utilizability in industry

The present invention can be suitable for the device of drying clothes.

Claims (4)

1. a device for clothing processing, is characterized in that comprising:

Treatment trough, for accommodating clothing;

Drive source, drives described treatment trough;

Main basket, accommodates described treatment trough and described drive source;

Support component, supports described treatment trough and decay to be passed to the vibration of described main basket from described treatment trough;

Drainage system, discharges the laundry water for the described clothing washed or in treatment trough described in rinsing outside described main basket; And

The circulatory system, makes the oven dry air circulation of the described clothing in the described treatment trough of oven dry, wherein,

The described circulatory system comprises the sensing element of the dehumidifying section dehumidified to described oven dry air and the dryness fraction measuring described clothing,

Described dehumidifying section comprises: the guiding tube comprising the inner face of the stream of the described oven dry air flowing of regulation; And in described stream for the feed water inlet that is applied to the dehumidifying water that described oven dry air dehumidifies, wherein, described guiding tube comprises the inflow entrance that the described laundry water that is supplied to described treatment trough and described oven dry air flow into,

Described drainage system comprises: the drainpipe guiding described laundry water outside described main basket; And connect the attaching parts of described inflow entrance and described drainpipe, wherein, described drainpipe comprises the fixed part of the face wall being fixed in described main basket,

Described sensing element comprises for measuring the temperature sensor being flowed into the temperature of the described dehumidifying water in described fixed part by described attaching parts,

Described temperature sensor comprises: contact with described fixed part thus measure the measuring cell of the temperature of described fixed part: and the holding wire be connected with described measuring cell,

Described fixed part comprises tube wall,

Described tube wall comprises: the internal face specifying the draining road of described dehumidifying water flow; And by the outside wall surface that described measuring cell pushes,

The temperature of the described dehumidifying water transmitted by described tube wall measured by described measuring cell.

2. device for clothing processing according to claim 1, is characterized in that:

Described fixed part keeps described holding wire, and described holding wire is to push the mode elastic deformation of described measuring cell to described fixed part.

3. device for clothing processing according to claim 1, is characterized in that:

Described fixed part comprises and protrudes from described outside wall surface and the holding cylinder keeping described measuring cell, wherein, forms the slit for inserting described holding wire in described holding cylinder.

4. the device for clothing processing according to claim 1 or 3, is characterized in that:

Described fixed part comprises the filter element removing Soft flocks from the laundry water by described drainage system.