EP2549008B1 - Basement arrangement of a heat pump laundry treatment apparatus - Google Patents

Basement arrangement of a heat pump laundry treatment apparatus Download PDF

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Publication number
EP2549008B1
EP2549008B1 EP11174986.7A EP11174986A EP2549008B1 EP 2549008 B1 EP2549008 B1 EP 2549008B1 EP 11174986 A EP11174986 A EP 11174986A EP 2549008 B1 EP2549008 B1 EP 2549008B1
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EP
European Patent Office
Prior art keywords
process air
region
blower
compressor
section
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Application number
EP11174986.7A
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German (de)
English (en)
French (fr)
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EP2549008A1 (en
Inventor
Sergio Pillot
Marco Santarossa
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Electrolux Home Products Corp NV
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Electrolux Home Products Corp NV
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Priority to EP11174986.7A priority Critical patent/EP2549008B1/en
Priority to CN201280036414.9A priority patent/CN103748279B/zh
Priority to PCT/EP2012/064098 priority patent/WO2013014045A1/en
Priority to AU2012289035A priority patent/AU2012289035B2/en
Priority to BR112014001390A priority patent/BR112014001390A2/pt
Priority to RU2014106475/12A priority patent/RU2014106475A/ru
Publication of EP2549008A1 publication Critical patent/EP2549008A1/en
Application granted granted Critical
Publication of EP2549008B1 publication Critical patent/EP2549008B1/en
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    • DTEXTILES; PAPER
    • D06TREATMENT OF TEXTILES OR THE LIKE; LAUNDERING; FLEXIBLE MATERIALS NOT OTHERWISE PROVIDED FOR
    • D06FLAUNDERING, DRYING, IRONING, PRESSING OR FOLDING TEXTILE ARTICLES
    • D06F58/00Domestic laundry dryers
    • D06F58/20General details of domestic laundry dryers 
    • D06F58/206Heat pump arrangements

Definitions

  • the invention relates to a laundry treatment apparatus having a heat pump system in which process air for laundry treatment is dehumidified and heated.
  • EP 1 209 277 A2 provides a heat pump tumble dryer having a compact base section that is supporting the main components of the heat pump system.
  • a battery channel housing the evaporator and the condenser are arranged at the left side of the base section and the compressor and motor for driving the process air blower and the rotatable drum are arranged at the right side.
  • the battery channel is part of the process air loop through which the process air for dehumidifying the laundry is guided from the drum outlet to the drum inlet.
  • Such arrangement has the advantage that integration of most heat pump and drum drive components in the base section leaves the open space in the middle and upper section of the dryer cabinet for arranging a big volume laundry drum that nearly fully extents from left to right and front to back in the cabinet.
  • WO 2008/155263 A1 suggests a similar arrangement for the main heat pump and drum drive components in the base section.
  • a laundry treatment apparatus having a laundry storing chamber for treating the laundry and a heat pump system for dehumidifying and heating process air vented through the laundry storing chamber.
  • the laundry treatment apparatus is a dryer, a washing machine or a washer-dryer.
  • the process air is circulated in a preferably closed process air loop that is formed by the flow path through the laundry storing chamber and a process air channel connecting the laundry storing chamber outlet to the chamber inlet.
  • the main components of the heat pump system (at least the first and second heat exchangers and the compressor) are arranged in a base section of the apparatus.
  • a section of the process air channel ('the process air duct section') is arranged in a middle region of the base section.
  • the process air duct section houses the first and second heat exchanger, wherein this arrangement of heat exchangers and duct section is sometimes called the 'battery' of the heat pump system.
  • the middle region, in which the process air duct section is arranged is extending from a middle front bottom region (in the base section) of the apparatus to a middle rear bottom region (in the base section) of the apparatus.
  • the middle zone or region of the base section is occupied by the process air duct section and in the horizontal plane (in the operation orientation of the apparatus) a first region of the base area of the base region is at a first side of or with respect to the process air duct section and a second region of the base area of the base region is at a second side of or with respect to the process air duct section.
  • first region is opposite to the second region with respect to the process air duct section or the process air duct section is between the first and second region.
  • the term 'middle region' may include the center with respect to the base section and may mean an extension of the process air duct section symmetrically along a center line of the base section. However 'middle region' also includes an arrangement of the process air duct section parallel to a center line through the base section (and preferably spatially including the centerline) where base areas of the base section to the left and right side of the process air duct section are not occupied by the process air duct section.
  • the main axis or main flow path through the process air duct section is vertically aligned or approximately vertically aligned to the main axis (e.g. rotation axis) of the laundry storing compartment.
  • the middle region is arranged below the laundry storing chamber and is preferably aligned to the main process air flow direction or the drum axis of the laundry storing chamber.
  • the direction of the center or main flow through the process air duct section (the battery channel) is parallel to the center line of the laundry storing chamber and in particular the center or main flow line through the process air duct section is vertically below thereto (i.e. the two center lines lie in a vertical plane).
  • the fraction of the total base area of the base section that is remained exposed or non-occupied by the process air duct section is at least 12%, 15%, 18%, 20%, 22% or 25% for each of the left and right sides.
  • One of the right or left side forms the first side region and the other forms the second side region of the base section which respectively occupies the side base areas at the sides of the process air duct section.
  • the base section comprises a bottom shell which has a structure to form the bottom wall and at least a part of the side walls of at least one or more of: the process air duct section, a process air front duct section, a process air rear duct section, and a process air rising duct section.
  • the bottom shell provides at least partially the base areas for the middle, first and second side regions.
  • the bottom shell provides the support structures for components of the apparatus, in particular of the heat pump system.
  • a cover or cover shell is provided that, when mounted on the bottom shell, closes or partially closes (e.g.
  • the cover or cover shell comprises support elements for mounting thereon rollers for rotatably supporting the rotatable laundry storing compartment (e.g. drum).
  • the bottom shell provides mounting and/or fixing locations and/or elements for one or more of the following: cabinet walls of the apparatus: a left side wall, a right side wall, a front wall, a rear wall and a bottom front cover panel.
  • the bottom shell provides mounting sites for electronic components, like power electronic components, of the apparatus.
  • the bottom shell is made of electrically insulating material, like plastics, so that mounting electronic components thereon provides electrical insulation.
  • the bottom shell and/or the cover shell are fabricated by injection molding.
  • the heat pump system has a refrigerant loop that has in this order the following components: A refrigerant compressor for circulating and compressing the refrigerant, a second heat exchanger for cooling the refrigerant and heating the process air, an expansion device for expanding the compressed refrigerant and a first heat exchanger for heating the refrigerant and cooling the process air, whereafter the refrigerant is feed back to the compressor's inlet.
  • the first heat exchanger is for example an evaporator or a gas heater in case of transcritical or totally critical refrigerant cycles.
  • the second heat exchanger (or if applicable an auxiliary heat exchanger) is for example a condenser or a gas cooler in case of transcritical or totally critical refrigerant cycles.
  • the expansion device may be a controllable valve that operates under the control of a control unit to adapt the flow resistance for the refrigerant in dependency of operating states of the heat pump system.
  • the expansion device can be a capillary tube, a valve with fixed expansion cross-section, a throttle valve with variable cross section that automatically adapts the expansion cross-section in dependency of the refrigerant pressure (e.g. by elastic or spring biasing), a semi-automatic throttle valve in which the expansion cross-section is adapted in dependency of the temperature of the refrigerant (e.g. by actuation of a thermostat and/or where the temperature of the refrigerant is taken at any of the components in thermal contact with the refrigerant.
  • an auxiliary heat exchanger it may be included in the refrigerant loop between the compressor and the second heat exchanger or between the second heat exchanger and the expansion device.
  • At least one component of the apparatus is arranged each on or at the first and second side region.
  • Such components are: power electronics, a drum drive motor, a process air blower motor, a drum drive electronic module or inverter, a compressor electronic module or inverter, the compressor, the refrigerant expansion device, the first or second heat exchanger, an auxiliary heat exchanger, a cooling air/process air heat exchanger.
  • the compressor is arranged at the first side region with respect to the process air duct section or middle region. And at least one or more of the following are arranged at the second side region with respect to the middle region:
  • the process air duct section fully or partially forms a 'shield' between the first side region and the second side region.
  • 'shielding' includes:
  • the apparatus By providing components of the apparatus divided between the first side region and the second side region, a more homogeneous weight distribution over the base area of the apparatus (which is the base area of the base section) is achieved. This facilitates storing, transporting and on-place positioning of the apparatus. Except the first and second heat exchanger, which are light weight per volume due to their open structure, the other components (e.g. compressor, motor, power electronics) to be arranged in the base section are normally heavy weight so that by the division onto two side regions at opposite ends of the base section results in the improved weight distribution as compared to the conventional base section arrangement.
  • the other components e.g. compressor, motor, power electronics
  • Another advantage of the distributed first side region / second side region arrangement results from improved accessibility to the components from the sides of the base section during assembling of the apparatus or during servicing of components.
  • the components in the basement can only be accessed from one apparatus side, while in the invention mounting and service can be performed from two sides.
  • the process air loop is preferably circulated in a closed loop in which the process air is preferably continuously flown through the laundry storing chamber.
  • a (preferably smaller) portion of the process air is exhausted from the process air loop and fresh air (e.g. ambient air) is taken into the process air loop to replace the exhausted process air.
  • fresh air e.g. ambient air
  • the process air loop is temporally opened (preferably only a small fraction of the total processing time) to have an open loop discharge - which e.g. may be used to remove smell from the laundry treated.
  • a condensate collection unit is arranged at the first side region, preferably in a back section of the first side region.
  • the condensate collection unit collects the condensate formed in the first heat exchanger in a condensate collection reservoir.
  • the condensate is collected in the reservoir only temporally and drained from there from time to time or in dependency of a condensate level in the reservoir as detected by a condensate level detector.
  • a condensate pump is used to drain the reservoir; preferably it is pumped to a second reservoir provided at an upper region of the apparatus for being emptied by a user.
  • the condensate is drained out of the process air duct section, in which the first heat exchanger is arranged, to the reservoir through a siphon that prevents process air loss out of the process air loop or entering of ambient air into the process air loop.
  • the condensate collection unit is provided at a front section of the first side region and preferably in this case the condensate reservoir or the second condensate reservoir can be removed by the user towards the front side of the apparatus for condensate removal.
  • the condensate collection unit is arranged in the first side region in a depth section that is arranged opposite to a depth section in the second side region where the blades of the process air blower are arranged.
  • the condensate collection unit and the blower are arranged in the rear sections of the respective first and second side region, a rearward extension of the condensate collection unit beyond the depth limit of the process air duct section or the rear or rising channel sections of the process air channel is avoided, thus assisting in keeping the depth extension of the apparatus low.
  • the blades of the process air blower are arranged in the middle region, preferably in alignment to the vertical cross section of the process air duct section, more preferably in line with the process air flow direction of the flow path through the process air duct section (i.e. the first and second heat exchangers).
  • the flow path length and thus the flow resistance is reduced in the flow section from the exit of the second heat exchanger to the blower.
  • a process air flow path and loop can be provided that does not require flow deflection and process air channel sections that run from a middle section to a side section and back.
  • the process air path is or is essentially in a plane that is defined by the main flow path axis through the laundry storing compartment (the rotation axis in case of a rotatable laundry storing compartment or drum) and the flow path through the process air duct section. In this case the required path length and number of process air deflections is significantly reduced.
  • the blades of the process air blower and/or a cooling air blower are driven by the motor which is the drum drive motor (in case of a rotatable laundry storing compartment).
  • the process air blower and/or a cooling air blower may be arranged on a rotating shaft of the motor or may be connected to the motor via transmission, e.g. by using a belt or gears.
  • the motor and the cooling air blower are arranged in the second side region and the cooling air blower sucks or blows the cooling air from or to the auxiliary heat exchanger and/or the power electronics.
  • a compressor blower is provided at the first side region to cool the compressor by blowing cooling air thereto or sucking cooling air therefrom. Cooling of the compressor and/or auxiliary heat exchanger is used to remove excessive heat from the heat pump system as soon as it has reached or is approaching its steady state condition.
  • the motor is arranged in the second side region opposite to the compressor with respect to the middle region. More preferably the compressor and motor are arranged in or close to a middle section of the respective first side region and second side region. In this way a weight balancing in the base section is achieved not only regarding left/right side, but also in view of rear/front sections of the base section.
  • the compressor is a variable speed compressor such that the refrigerant conveyance rate and/or refrigerant pressure can be controlled by the control unit of the apparatus by corresponding control of the compressor speed.
  • the refrigerant pressure and/or temperature is detected by the control unit using sensor(s) and the compressor speed is modified in dependency of the detected temperature and/or pressure.
  • the drum motor speed and/or the process air blower speed can also be varied under the control of the control unit.
  • Fig. 1a and 1b show a perspective and a top view to a base section 2 of a conventional heat pump tumble dryer and Fig. 1c shows the perspective view of the base section with a cover shell mounted and a drum 30 rotatably supported on the cover shell.
  • the heat pump tumble dryer uses a heat pump system for dehumidifying and heating process air that is circulated in a closed process air loop through drum 30.
  • the components of the heat pump system are arranged and mounted in a bottom shell 4 forming the lower part of the base section 2.
  • the structure of the bottom shell 4 provides part of the process air channel, mounting structures for components, dryer foots, venting openings, support brackets and so on.
  • the heat pump system comprises a refrigerant loop in which a compressor 22 for pressurizing and pumping the refrigerant, a second heat exchanger 8 (condenser or gas cooler for heating the process air), an expansion device (no reference numeral shown), and a first heat exchanger 6 (evaporator or gas heater for cooling and dehumidifying the process air) are arranged in this flow direction order.
  • a compressor 22 for pressurizing and pumping the refrigerant
  • a second heat exchanger 8 condenser or gas cooler for heating the process air
  • an expansion device no reference numeral shown
  • a first heat exchanger 6 evaporator or gas heater for cooling and dehumidifying the process air
  • the process air flow P1 of the conventional dryer is schematically indicated in Fig. 1c
  • Fig. 1c When it exits the drum 32 at the drum side forming the loading opening, it enters a descending process air channel section at the front side of the dryer. Only a portion of this process air channel is shown in the figures immediately in front of the first heat exchanger 6 and being denoted with reference numeral 12.
  • This lower front section of the process air channel receives a fluff filter drawer (not shown) and represents the filter compartment channel 12.
  • the process air After passing the fluff filter in the filter compartment channel 12 the process air enters a battery channel 10 in which the first and second heat exchangers 6, 8 are housed.
  • This channel section with the heat exchangers is also called the heat pump battery.
  • the process air outlet from the second heat exchanger 8 is guided in a rear channel 14 to the inlet of a radial blower 18.
  • the process air blower 18 conveys the process air in a rising channel 16 arranged at the rear side of the dryer upwards to the rear opening of the drum 32 where it enters the drum 32 and dries the laundry stored therein.
  • the blades of the process air blower 18 are supported on a shaft of drum driving motor 20.
  • Motor 20 drives a belt (not shown) that is disposed around drum 32 to drive it.
  • a condensate unit 24 is arranged for collecting and draining the condensate that was formed in or at the first heat exchanger 6 by cooling the process air.
  • the bottom shell 4 has condensate channels on its bottom to collect and guide the condensate from the first heat exchanger 6 into a condensate reservoir 26 of unit 24 where it is temporally collected.
  • the unit 24 has a level detector 28 sending a level signal to a control unit of the dryer (not shown) at a predetermined condensate water level and the control unit activates a condensate pump 30 of the condensate unit 24 to drain the condensate from the condensate reservoir 26 to a condensate drawer (not shown) which is arranged at a top section of the dryer.
  • the functional components arranged in the base section 2 can be grouped in three main zones, namely on the left side zone K comprising the filter compartment channel 12, the battery channel 10 including the first and second heat exchangers 6, 8 and most portion of rear channel 14.
  • the right side zone L comprises the compressor 22 and the motor 20 (and a smaller portion of rear channel 14).
  • the rear zone M comprises the blades of process blower 18, the lower section of rising channel 16, and the condensate unit 24.
  • the ground area of the dryer has a width W 1 of 60 cm and a depth D 1 of 60 cm.
  • Fig. 1c further indicates the basic air flow of the process air flow P1 through the drum 32, the front channel (only portion thereof shown by filter compartment channel 12), battery channel 10, rear channel 14, blower 18 and rear channel (only portion thereof shown by rising channel 16).
  • the process air channel sections in the base section 2 are covered by a cover shell 34 which has roller supports 36 integrated therewith for rotatably supporting drum 32 on bearing reels.
  • Figs. 2a, 2b , 3a to 3c and 4 show embodiments of a base section 42, 42a and 42b according to the invention, respectively.
  • the difference to the conventional base section 2 shown in Figs. 1a to 1c is the arrangement of the dryer components, in particular the heat pump components, in the base sections.
  • the operation and function of the components are similar or identical to the respective component described above in respect of the conventional dryer base section 2, wherein identical terms are used for the same components.
  • This specifically relates to the order of components in the process air loop and in the refrigerant loop.
  • the features, elements and their interrelation as mentioned above applies for the following embodiments.
  • the elements and features described above and in the following can be combined or arranged in different combinations and partial combinations which are all included in the disclosure.
  • the groups or zones I, II, III of components of the dryer and its heat pump system are arranged different to the zones K, L, M shown in Fig. 1b .
  • the first zone I forms a middle or center region of the base section 42 that extends from the front center region to the back center region of the base section, i.e. the front bottom center region to the bottom back center region of the dryer.
  • Middle zone I comprises from front to back the filter compartment channel 52, the middle or battery channel 50 with the first and second heat exchangers 46, 48, most portion of the rear channel 54, and a portion of the rising channel 56.
  • the left zone II is arranged at the left side of the base section 42 and comprises the compressor 62 and the condensate unit 64 having the condensate reservoir 66, the level detector 68 and the condensate pump 70.
  • the right zone III is arranged on the right side of basement section 42 and comprises the motor 60, the smaller portions of the rear channel 54 and portion of rising channel 56, and the blades of process air blower 58.
  • the middle zone I, the left zone II and the right zone III extend from the very front to the very back of the base section 42 (which corresponds to the front to the back of the dryer - see also the following embodiments).
  • the support, bottom and mounting structure of the base section 42 is mainly provided by a bottom shell 44a, in which for example the bottom walls and completely or at least partially the side walls of the filter compartment channel 52, the rear channel 54, the middle channel 50 and the rising channel 56 are formed, unless inlet or outlet openings between the channels or to the section of the dryer above the bottom section level are provided (e.g. inlet opening in filter compartment channel having also a fluff filter insertion opening or outlet opening in rising channel).
  • a similar structure is provided by bottom shells 44a and 44b for base sections 42a and 42b, respectively.
  • Fig. 2a shows a rectangle A which indicates the depth or ground area reduction that is achieved by the regrouping of components in the base section 42 (having depth D2) as compared to the conventional base section 2 (having depth D1).
  • base sections 42a and 42b wherein the base section dimension essentially or identically correspond to the base or ground dimensions of the dryer.
  • the width W2 of base section 42 is identical to the conventional width W1, e.g. 60 cm.
  • the depth D2 of base section 42 is about or less than 57 cm, 55 cm, 53 cm or 50 cm.
  • the ratio of depth D2 to width W2 is less than unity or less than or about 0.95, 0.90, 0.85, 0.80 or 0.70.
  • the ground area requirement and in particular the installation depth of the dryer is reduced as compared to the conventional dryer and the inventive dryer is more convenient for single or two user apartments.
  • the drum volume can be reduced due to the reduced drum axial length (compare drums in Figs. 1c and 3c )
  • the components of the heat pump system can be dimensioned for lower maximum power, which reduces component's size and overall energy consumption.
  • Fig. 3 a shows a perspective view of another embodiment of a base section 42a in which a cover shell 72 is shown in a lifted position.
  • the cover shell 72 is in its final or mounting position where it is mounted the bottom shell 44a.
  • Bottom shell together with cover shell 72 form the process air channel sections for the middle channel 50, the filter compartment channel 52, the rear channel 54a and portion of the rising channel 56a (see above).
  • the blades of the process air blower 58a are enclosed by the two shell parts of the rising channel 56a wherein an inlet passage to the rear channel 54a is provided and an outlet passage to upper part of rising channel 56a towards the drum 76.
  • Roller supports 74 are integrally formed at the cover shell 72 which have bearing rollers for rotatably supporting the drum 76 ( Fig. 3c ).
  • blower 58a As compared to the embodiment of Fig. 2a , in the embodiment of Figs. 3a to 3c the blower is aligned to the process air flow direction in the battery channel 50.
  • Rear channel 54 does not need to laterally deflect the process air output from the second heat exchanger 48 from zone I to zone III (compare Fig. 2a ), but it has more a concentrating or hopper function and shape to guide the air flow from the battery channel 50 to the suction inlet of blower 58a.
  • the blades of blower 58a are driven by motor 60 using a belt 59 guided between the shaft of motor 60 and the bearing shaft (not shown) of blower 58a.
  • the blower 58a and the drum 18 are each driven by separate motors.
  • the drum 18 is driven by motor 60 as shown in the figures and the blower 58a is an integrated unit having the motor integrated and forming an independently driven blower, for example having radial or centrifugally conveying blades (as the blower 58a shown).
  • the compressor 62 and the condensate unit 64 are arranged in the left zone II as in Fig. 2a with the difference that the components 62, 68 and 70 are slightly shifted or rotated without functional difference.
  • Fig. 3c further shows the process air flow path P2 through the drum 76, the front channel (only portion thereof shown by filter compartment channel 52), battery channel 50, rear channel 54a, blower 58a and rear channel (only portion thereof shown by rising channel 56a).
  • the path length and the number of deflections and curves in the flow path P2 is significantly reduced.
  • Flow path P2 is essentially in one plane in which the drum rotation axis lies.
  • the second straight line for spanning the plane of the flow path P2 is the vertical direction of the dryer when positioned in its normal operation position.
  • blower 58 used in the embodiment of Fig. 3c requires a lower blowing capacity as compared to blower 18 used in the conventional dryer of Fig. 1c .
  • Lower blowing capacity also facilitates to use blower 58 with smaller blade and/or drive motor dimensions and less power consumption (for the process air blowing operation).
  • the dimensional requirements (blower blade, housing for blower blade) are reduced assisting in providing a more compact dryer.
  • the channel length is reduced - again providing a more compact design.
  • Fig. 2a and 2b provides a deflection of the process air path in the rear channel 54 from center bottom rear side to right bottom rear side and from there in the rising channel 56 from right bottom back side to higher center back side (at the drum rear inlet), the flow path at the front side is shorter and with reduced deflection locations as compared to flow path P1.
  • P2 has an optimized geometry
  • the flow path in the embodiment of Figs. 2a and 2b still has a reduced flow resistance and a shorter flow path as compared to the conventional dryer shown in Figs. 1a to 1c , such that the advantages of the embodiment of Figs. 3a to 3c at least partially applies.
  • Fig. 1c and 3c shows that in the inventive embodiments the drum depth is reduced as compared to the drum depth of the conventional drum 32, while the diameter dimension is the same or essentially the same.
  • the maximum drying power, i.e. the cooling/heating power, of the heat pump system is reduced.
  • This enables using heat pump components of reduced dimensions as compared to the components of a conventional heat pump system.
  • This results in an improved drying efficiency or energy reduction when normally smaller laundry loads or volumes have to be dried, e.g. laundry volumes that are typical for single household or couple households as compared to family households.
  • the reduced dimensional requirement for the heat exchangers enables reducing the cross section area (cross to the process air flow) of the middle channel 50 which in turn allows providing the components on both channel sides.
  • FIG. 4 Another embodiment of a base section 42b is shown in Fig. 4 .
  • the middle or battery channel 50 with the first and second heat exchanger 46, 48 and most portion of the rear channel 54 are arranged at the middle zone I (compare embodiment in Fig. 2a ).
  • the bottom portion of the base section 42b is provided by a bottom shell 44b which comprises most of support, mounting and channel structure of the base section.
  • the blower 58, blower motor 60, a compressor blower 86 and compressor 62 are arranged at the right side or third zone III.
  • the compressor blower 86 is mounted on the shaft of drum drive motor 60 and blows cooling air towards the compressor 62. In an embodiment compressor blower 86 sucks cooling air from the compressor.
  • auxiliary or first cooling air blower 80, an auxiliary heat exchanger 82, a compressor power converter 84 and the condensate unit 64 are arranged on a left side or second zone II.
  • the battery channel 50 is forming a center or middle section of the base section 5 running from a front region (filter compartment channel 52) to the back region (rear channel 54) of the base section 42b.
  • the compressor blower 86 may have its own driving motor so that blower 58 and 86 can be independently driven. This has the advantage that blower 86 is started only when the steady state of operation of the heat pump system is reached or is approached. Also the speed of blower 86 can be adapted by the control unit in dependency of need to remove excess heat from the heat pump system.
  • the compressor blower 86 cools the compressor and removes excessive heat from the heat pump system as soon as the heat pump system has achieved a steady state after the warm-up period.
  • the auxiliary heat exchanger 82 in combination with cooling air blower 80 serves the same purpose, wherein the auxiliary heat exchanger 82 is connected in the refrigerant loop of the heat pump system between the compressor 62 and the second heat exchanger 48 or between the second heat exchanger 48 and the expansion device.
  • cooling air blower 80 generates a cooling air flow A that is sucked in through front openings in the base section 42b, is blown through auxiliary condenser 82, through and/or over power converter 84 and is deflected by the side wall of the condensate unit 64 to the outside of the base section through openings formed therein.
  • the cooling air flow is sucked in by blower 80 through openings in the front region of the base section 42b, is pushed by the blower 80 through the heat exchanger 82 towards power converter 84, is deflected by the outer case of the condensate unit 64 to the side and exits the base section through openings at a side wall thereof.
  • the cooling air flow is reversed and/or the blower 80 is arranged on the rear side of heat exchanger 82 (when seen from the front of the dryer).
  • blower 80 is activated by the control unit as soon as the refrigerant temperature at a predefined location of the refrigerant loop has reached or exceeded a predefined temperature.
  • the compressor blower 86 is provided in the embodiments of Figs. 2a and 3a .
  • other power electronics like a drum motor 60 power converter
  • Reference Numeral List 2 basement section 56, 56a rising channel 4 bottom shell 58, 58a process air blower 6 first heat exchanger 59 belt 8 second heat exchanger 60 motor 10 battery channel 62 compressor 12 filter compartment channel 64 condensate unit 14 rear channel 66 condensate reservoir 16 rising channel 68 level detector 18 process air blower 70 condensate pump 20 motor 72 cover shell 22 compressor 74 roller support 24 condensate unit 76 drum 26 condensate reservoir 80 cooling air blower 28 level detector 82 auxiliary heat exchanger 30 condensate pump 84 power converter 32 drum 86 compressor blower 34 cover shell 36 roller support I, II, III zones A area 42, 42a, 42b basement section C cooling air flow 44, 44a, 44b bottom shell K, L, M zones 46 first heat exchanger W1, W2 width 48 second heat exchanger D1, D2 depth 50 middle channel P1, P2 process air flow 52 filter compartment channel 54, 54a rear channel

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  • Engineering & Computer Science (AREA)
  • Textile Engineering (AREA)
  • Detail Structures Of Washing Machines And Dryers (AREA)
  • Compressor (AREA)
EP11174986.7A 2011-07-22 2011-07-22 Basement arrangement of a heat pump laundry treatment apparatus Active EP2549008B1 (en)

Priority Applications (6)

Application Number Priority Date Filing Date Title
EP11174986.7A EP2549008B1 (en) 2011-07-22 2011-07-22 Basement arrangement of a heat pump laundry treatment apparatus
CN201280036414.9A CN103748279B (zh) 2011-07-22 2012-07-18 衣物处理设备
PCT/EP2012/064098 WO2013014045A1 (en) 2011-07-22 2012-07-18 Basement arrangement in heat pump laundry treatment apparatus
AU2012289035A AU2012289035B2 (en) 2011-07-22 2012-07-18 Basement arrangement in heat pump laundry treatment apparatus
BR112014001390A BR112014001390A2 (pt) 2011-07-22 2012-07-18 aparelho para tratamento de roupa para lavar
RU2014106475/12A RU2014106475A (ru) 2011-07-22 2012-07-18 Конструкция основания в устройстве для обработки белья с тепловым насосом

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EP11174986.7A EP2549008B1 (en) 2011-07-22 2011-07-22 Basement arrangement of a heat pump laundry treatment apparatus

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EP2549008B1 true EP2549008B1 (en) 2015-06-10

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AU (1) AU2012289035B2 (pt)
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WO2022169341A1 (en) * 2021-02-08 2022-08-11 Lg Electronics Inc. Laundry treating apparatus
WO2022169313A1 (en) * 2021-02-08 2022-08-11 Lg Electronics Inc. Laundry treating apparatus

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KR102302326B1 (ko) 2014-10-28 2021-09-15 엘지전자 주식회사 의류처리장치
KR101613966B1 (ko) * 2014-12-29 2016-04-20 엘지전자 주식회사 의류처리장치
WO2016108790A1 (en) * 2014-12-30 2016-07-07 Arçeli̇k Anoni̇m Şi̇rketi̇ A washing machine comprising a heat pump
KR101711869B1 (ko) * 2015-01-13 2017-03-03 엘지전자 주식회사 건조기
EP3323933B1 (en) * 2015-06-19 2021-07-21 LG Electronics Inc. Clothes dryer and method for controlling the same
CN106521908A (zh) * 2015-09-09 2017-03-22 无锡小天鹅股份有限公司 干衣机
CN106930076B (zh) * 2015-12-31 2019-05-21 无锡小天鹅股份有限公司 干衣机
CN105937168B (zh) * 2016-05-31 2020-10-20 无锡小天鹅电器有限公司 干衣机或洗干一体机
CN107761340A (zh) * 2016-08-19 2018-03-06 博西华电器(江苏)有限公司 具有风扇的衣物烘干机
EP3505040B1 (de) * 2018-01-02 2022-05-04 Miele & Cie. KG Geschirrspülmaschine, insbesondere haushaltsgeschirrspülmaschine
PL3617390T3 (pl) * 2018-08-30 2022-07-11 Electrolux Appliances Aktiebolag Suszarka do prania zawierająca układ pompy ciepła
PL3617392T3 (pl) * 2018-08-30 2022-09-26 Electrolux Appliances Aktiebolag Suszarka do prania zawierająca system pompy ciepła
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Publication number Priority date Publication date Assignee Title
WO2022169327A1 (en) * 2021-02-08 2022-08-11 Lg Electronics Inc. Laundry treating apparatus
WO2022169341A1 (en) * 2021-02-08 2022-08-11 Lg Electronics Inc. Laundry treating apparatus
WO2022169313A1 (en) * 2021-02-08 2022-08-11 Lg Electronics Inc. Laundry treating apparatus

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CN103748279A (zh) 2014-04-23
WO2013014045A1 (en) 2013-01-31
AU2012289035B2 (en) 2017-03-02
BR112014001390A2 (pt) 2017-02-21
RU2014106475A (ru) 2015-08-27
AU2012289035A1 (en) 2014-02-06
EP2549008A1 (en) 2013-01-23
CN103748279B (zh) 2016-08-17

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