WO2018050011A1 - 一种高效冷凝器和具有该冷凝器的洗衣机 - Google Patents

一种高效冷凝器和具有该冷凝器的洗衣机 Download PDF

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Publication number
WO2018050011A1
WO2018050011A1 PCT/CN2017/100672 CN2017100672W WO2018050011A1 WO 2018050011 A1 WO2018050011 A1 WO 2018050011A1 CN 2017100672 W CN2017100672 W CN 2017100672W WO 2018050011 A1 WO2018050011 A1 WO 2018050011A1
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Prior art keywords
heat exchange
exchange tube
condenser
efficiency
layer
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PCT/CN2017/100672
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English (en)
French (fr)
Inventor
李以民
劳春峰
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青岛海尔滚筒洗衣机有限公司
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Publication of WO2018050011A1 publication Critical patent/WO2018050011A1/zh

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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
    • D06F58/32Control of operations performed in domestic laundry dryers 
    • D06F58/34Control of operations performed in domestic laundry dryers  characterised by the purpose or target of the control
    • D06F58/45Cleaning or disinfection of machine parts, e.g. of heat exchangers or filters
    • 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 
    • D06F58/22Lint collecting arrangements
    • 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 
    • D06F58/24Condensing arrangements

Definitions

  • the invention belongs to the field of washing and drying machines, and in particular to a high efficiency condenser and a washing machine having the same.
  • washing and drying machines are divided into drum type and cabinet type according to the structure, and most of them are drum type.
  • the drum type dryer is generally composed of a box body, a drum system, a hot air system, a transmission and a control system; according to the water discharge mode, it is divided into: an exhaust type and a dehumidification type, and the exhaust type is a high temperature and high humidity formed by evaporating water inside the machine. The air is directly discharged to the outside of the machine.
  • the dehumidification type is to discharge the condensed water through the heat exchanger through the high temperature and high humidity air, and then discharge it to the outside of the machine.
  • the condensing drying system of the drum washing machine is provided with a condenser in the circulating air passage.
  • the dry hot air heats the moisture in the wet clothes into steam.
  • the condenser passes through the condenser, the steam is cooled and discharged into the outside of the washing machine, and the condensed dry air passes through.
  • the fan and the heater become dry hot air, and the clothes are blown again until the moisture in the clothes is all turned into steam, and then the steam is condensed and turned into water to be drained for drying purposes.
  • the temperature and humidity of the hot air are determined.
  • the temperature of the hot air depends on the power of the heater. It is determined by the heat resistance of the fiber.
  • the humidity of the hot air is the water vapor content.
  • the ability of the water vapor to become distilled water depends on the condensation capacity of the condenser, so the condensation capacity of the condenser is increased. Improve drying efficiency.
  • the following two methods are generally adopted: one is to perform fan cooling or water spray cooling on the outer surface of the condenser casing and the hot air pipe, and the other is to use a scattered water inside the condenser or inside the air duct to cool down.
  • Cida Patent No. CN200610000722.2 discloses "a condensing structure for drying a drying system of a washing machine efficiently" comprising a condensing duct, a condensate inlet pipe, and at least one condensing device fixedly disposed in the condensing duct: One end of the condensing device is provided with a condensate spray device connected to the condensate inlet pipe to cool the condensing device. Above the condensing device is provided a condensate spray device connected to the condensate inlet pipe for facilitating passage of condensed water along the condensing plate.
  • the invention does not solve the problem of gas-liquid mixing in the condensation process, and does not fully utilize the space in the condenser, the heat exchange area cannot be controlled, and the utilization is insufficient, and at the same time, part of the condensate is brought back into the air circulation system. Reduce the efficiency of dry clothes.
  • a self-cleaning filter device for a clothes dryer includes a condenser, a filter net, a air duct, a water storage box, a water storage tank, a drain pump, and a drain pipe between the water storage tank and the drain pump.
  • a water level sensor is arranged in the water storage tank, and a sprinkler is also arranged, which is arranged in the air duct, is located between the filter net and the condenser, and is a T drain pipe for connecting a water storage tank and a shower; a first sensor located in the air duct to sense the accumulation of wire debris on the filter net; the controller receiving signals transmitted by the first sensor and the water level sensor, respectively issuing commands to control the drain pump and the shower Turn it on and off.
  • the position of the shower of the present invention is located between the filter and the condenser, and a sensor is provided, which increases the complexity of the device, and when the sensor fails, the spray mechanism will not function properly.
  • the present invention has been made in view of the above.
  • the technical problem to be solved by the present invention is to overcome the deficiencies of the prior art, and provide a high-efficiency condenser and a washing machine having the same, which successfully realizes the gas-liquid separation of the condensation process and makes the heat exchange between the heat exchange mediums sufficient and condenses.
  • the efficiency is improved, and the shower is provided with a shower device to flush the accumulated dust, thereby shortening the drying time of the washing and drying machine.
  • a high-efficiency condenser is applied to a washing and drying machine, wherein the condenser is a cavity structure having an upper width and a lower width and a lower portion bent to one side, comprising:
  • the outer casing has an air inlet connected to the outer cylinder of the washing machine at the lower part, and an air outlet at the top is connected with the fan in the drying air duct, and the side with the smaller radius of curvature of the lower curved portion is the inner side, and the side with the larger radius of curvature The side is the outer side;
  • the heat exchange tube is disposed in the outer casing to exchange heat with the moist hot air, hollow and bent into a multi-layer structure, and the heat exchange tubes in each layer are bent into a serpentine spring-shaped heat exchange tube, and the adjacent two layers of heat exchange There are interlayer gaps between the tubes;
  • a spray box disposed above the heat exchange tube for rinsing the wire scraping on the heat exchange tube
  • Condensate drain located at the bottom of the condenser for draining condensate from the condenser to the washing machine drain.
  • the outer diameter of the heat exchange tube is constant, the thickness of the heat exchange tube is constant, the interlayer gap is constant, and the pitch of the serpentine spring-shaped heat exchange tube in the same layer is gradually increased from the outer side to the inner side. .
  • the thickness of the heat exchange tube is constant, the interlayer spacing of the center line of the heat exchange tube is constant, the pitch of the serpentine spring-shaped heat exchange tube in the same layer is unchanged, and the outer diameter of the heat exchange tube is from the outer side to the inner side. The sides are gradually reduced.
  • the interlayer gap of the heat exchange tube is fixed, the pitch of the serpentine spring-shaped heat exchange tube in the same layer is fixed, the outer diameter of the heat exchange tube is constant, and the inner diameter of the heat exchange tube gradually increases from the outer side to the inner side. Reduced.
  • the interlayer gap of the heat exchange tube is fixed, the pitch of the serpentine spring-shaped heat exchange tube in the same layer is fixed, the outer diameter of the heat exchange tube is constant, and the inner diameter of the heat exchange tube is gradually reduced from the lower layer to the upper layer.
  • the thickness of the heat exchange tube is constant, the interlayer spacing of the center line of the tube is constant, and the serpentine spring-shaped heat exchange tube in the same layer
  • the pitch of the heat exchange tube is constant, and the outer diameter of the heat exchange tube is gradually reduced from the lower layer to the upper layer.
  • the heat exchange tube has an outer diameter of 2-15 mm.
  • the heat exchange tube inlet port is located at the upper end of the condenser and is connected to the low temperature liquid line
  • the liquid discharge port is located at the lower end of the condenser and connected to the high temperature liquid line.
  • the upper part of the heat exchange tube has a spray box, wherein the spray box has a hollow cavity structure, the top has a water inlet, and the bottom part is a spray surface with a plurality of spray water outlets.
  • the water inlet is connected to a water inlet pipe of the washing machine.
  • the present invention has the following advantageous effects compared with the prior art.
  • the high-efficiency condenser and the washing machine with the same disclosed in the invention successfully realize the gas-liquid separation of the condensation process, and overcome the disadvantages of the existing condenser which directly condenses with the spray cold water, so that the heat exchange process
  • the heat exchange area in the area is fixed and controllable.
  • the multi-layered serpentine spring-shaped heat exchange tube of the invention increases the contact area of the heat exchange device and the moist hot air; and comprehensively adjusts the serpentine spring-shaped heat exchange tube by combining the air flow direction in the internal cavity of the condenser
  • the density, the outer diameter and the inner diameter are various ways to fully utilize the overall area of the heat exchanger, and the heat exchange efficiency between the hot and humid air and the heat exchange tube is greatly improved.
  • the upper part of the heat exchange tube is further provided with a spray box, and the spray box uses the water flow to flush the wire sticking on the heat exchange tube, thereby avoiding the heat exchange efficiency drop and the bacteria breeding caused by the pile dust accumulation, not only
  • the heat exchange efficiency is improved, the overall drying time of the washing and drying machine is shortened, and the hygienic environment of the washing and drying machine is also improved.
  • Figure 1 is a partial cross-sectional view showing a washing and drying machine using the present invention
  • Figure 2 is a schematic view showing the appearance of a washing and drying machine using the present invention
  • Figure 3 is a schematic cross-sectional view of the condenser assembly of the present invention.
  • Figure 4 is a schematic view of the condenser assembly of the present invention.
  • Figure 5 is a schematic view of a heat exchange tube of the condenser of the present invention.
  • Figure 6 is a schematic view showing the appearance of a shower box of the condenser of the present invention.
  • Figure 7 is a schematic cross-sectional view showing the shower box of the condenser of the present invention.
  • connection In the description of the present invention, it should be noted that the terms “installation”, “connected”, and “connected” are to be understood broadly, and may be fixed or detachable, for example, unless otherwise explicitly defined and defined. Connected, or integrally connected; can be mechanical or electrical; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present invention can be understood in a specific case by those skilled in the art.
  • the condenser 1 is a cavity structure with an upper width and a lower width and a lower portion bent to one side, comprising: a casing 5, the lower portion is provided with an air inlet 8 connected to the outer cylinder 13 of the washing machine, and the air outlet 9 is opened at the top and baked.
  • the fan 15 in the dry air duct 17 is connected, the side of the lower curved portion having the smaller radius of curvature is the inner side 18, the side having the larger radius of curvature is the outer side 19, and the heat exchange tube 4 is disposed on the outer casing 5.
  • the invention realizes the gas-liquid separation of the condensation process, and the density, the outer diameter and the inner diameter of the heat exchange tube are large The small change setting makes the heat exchange more complete and the condensation efficiency is improved, thereby improving the drying efficiency of the washing and drying machine.
  • the high-efficiency condenser 1 in this embodiment is applied to a washing and drying machine.
  • the condenser 1 is a cavity structure having an upper width and a lower width and a lower portion bent to one side, and includes:
  • the outer casing 5 has a lower air inlet 8 connected to the outer casing 13 of the washing machine, and an air outlet 9 at the top is connected to the fan 15 in the drying duct 17, and the side of the lower curved portion having the smaller radius of curvature is the inner side. 18, the side of the side having a large radius of curvature is the outer side 19;
  • the heat exchange tube 4 is disposed in the outer casing 5 to exchange heat with the moist hot air, is hollow and is bent into a multi-layer structure, and the heat exchange tubes in each layer are bent into a serpentine spring-shaped heat exchange tube 4, adjacent to the two
  • the layer heat exchange tube has an interlayer gap, the liquid inlet 6 of the heat exchange tube 4 is located at the upper end of the condenser 1 and is connected to the low temperature liquid pipeline, and the liquid discharge port 3 is located at the lower end of the condenser 1 and is connected with the high temperature liquid pipeline.
  • the low temperature pipeline and the high temperature pipeline are only relative to the temperature comparison of the liquid before and after the heat exchange, and do not represent the meaning of absolute temperature;
  • a spray box 7 disposed above the heat exchange tube 4 for rinsing the wire scraping on the heat exchange tube 4;
  • the condensate drain 2 is located at the bottom of the condenser 1 for discharging the condensed water in the condenser 1 to be connected to the washing machine drain.
  • the washing and drying machine using the condenser of the present invention in the embodiment includes an outer cylinder 13, a motor 14, a drying duct 17, a fan 15, a condenser 1 and the like, and the fan 15 is disposed at The front end of the air duct 17 is dried, and the condenser 1 is disposed at the front end of the fan 15.
  • a heater 16 is provided inside the washing and drying machine drying duct 17. When drying the laundry, the air is first heated by the heater 16, and the hot air is driven into the washing tub by the fan 15 to heat the residual moisture on the clothes into water vapor, and the water vapor enters the condenser with the hot air driven by the fan 15. 1.
  • the water vapor is condensed in the condenser 1 into liquid water and drained through the condensate drain 2 at the bottom of the condenser 1, and the relatively dry air is again heated by the heater 16 into the washing tub to participate in the drying cycle. After a certain period of circulation, the clothes are dried.
  • the condenser assembly of this embodiment is shown in Fig. 4.
  • the condenser assembly includes a condenser 1, a heat exchange tube 4, a shower box 7, and the like.
  • the upper part of the condenser 1 is an air outlet 9, the air outlet 9 is connected to the inlet of the fan 15, the lower part of the condenser 1 is provided with an air inlet 8, and the air inlet 8 is connected to the air outlet of the outer cylinder 13.
  • the bottom of the condenser 1 is provided with a condensate drain 2 for discharging liquid water formed by condensation of water vapor.
  • the spray box 7 is provided at the upper portion of the condenser 1. As shown in FIG.
  • the heat exchange tubes 4 are bent into a multi-layer structure, and the heat exchange tubes in each layer are bent into a serpentine spring-shaped heat exchange tube 4, and interlayer gaps between adjacent two layers of heat exchange tubes are shown.
  • the cooling water flows into the heat exchange tube 4 through the liquid inlet 6 and flows along the internal passage through the liquid discharge port 3, and the cooling water flows through the heat exchange tube 4 and
  • the humid hot air flowing into the air inlet 8 of the condenser 1 is sufficiently heat exchanged to condense the water vapor carried by the hot humid air flow.
  • the liquid water flows out of the condenser 1 through the condensate drain 2 and then exits the machine.
  • the low temperature liquid in the heat transfer tubes 4 of the condenser 1 flows downward from the upper portion, and the moist hot air flows from the bottom to the upper side, and such an arrangement can improve the efficiency of heat exchange.
  • the liquid inlet port 6 and the liquid discharge port 3 are respectively disposed at the upper and lower ends thereof.
  • the liquid inlet port 6 is connected to the water inlet pipe of the washing and drying machine, and the liquid discharging port 3 is connected to the drain pipe of the washing and drying machine.
  • the liquid inlet is introduced.
  • the port 6 can also be connected to other heat exchange liquid medium to achieve the purpose of filling the heat exchange tube 4 with a flowing cryogenic liquid.
  • the heat exchange tube 4 has a multi-layer structure, and the heat exchange tubes in each layer are bent into a serpentine spring-shaped heat exchange tube 4, and the adjacent two layers of heat exchange tubes have interlayer gaps, so that they have a large surface area, so The cooling water flowing through the inside thereof can sufficiently exchange heat with the moist hot gas stream, and has good condensation efficiency.
  • the heat exchange tubes 4 of the present invention are made of copper, copper alloy, aluminum, aluminum alloy or other materials having good thermal conductivity.
  • the outer diameter of the heat exchange tube is generally 2-15 mm, and the preferred outer diameter of this embodiment is 4-8 mm.
  • the heat exchange tube 4 of the present invention has a multi-layer structure, and the heat exchange tubes in each layer are bent into a serpentine spring-shaped heat exchange tube 4, and the adjacent two layers of heat exchange tubes have interlayer gaps and have a large surface area. Therefore, when the cold water flows through the heat exchange tube 4, it can sufficiently exchange heat with the moist heat flow, and has high condensation efficiency.
  • the washing and drying machine using the condensation method can significantly improve the condensation efficiency, greatly shorten the drying time, and has a good energy saving effect.
  • the distribution of the heat exchange tubes 4 is such that the density of the heat exchange tubes 4 near the outer side 19 of the heat exchange tubes is greater than the density of the heat exchange tubes 4 at the inner sides 18, and this change is a smooth transition.
  • the condenser 1 is provided as a cavity structure in which the upper portion is narrow and the lower portion is curved toward one side. In such a cavity structure, the flow of the moist hot air is not uniform, that is, the hot humid air flows at a speed on the side of the outer side 19 much faster than the side of the inner side 18 side.
  • the heat exchange tube 4 has a density of the heat exchange tubes 4 near the outer side 19 greater than the density of the heat exchange tubes 4 on the inner side 18, on the one hand, the heat exchange tubes 4 are externally added.
  • the number of heat exchange medium per unit area in the side 19 increases the heat exchange rate, and on the other hand, by reducing the gap of the outer side 19, the hot humid air also flows in the condenser 1 on the outer side 19 side.
  • the greater wind resistance allows the air to flow evenly in the cavity of the condenser 1 to better utilize the heat exchange medium of the inner side 18 portion.
  • the condensation effect of the condenser is improved, and the drying efficiency of the dry washing machine is improved.
  • the difference between the embodiment and the embodiment 1 is that the thickness of the heat exchange tube is constant, the interlayer spacing of the center line of the heat exchange tube is constant, and the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is unchanged.
  • the outer diameter of the heat pipe gradually decreases from the outer side 19 to the inner side 18.
  • the distribution manner of such a heat exchange tube 4 is such that although the pitch of the serpentine spring-shaped heat exchange tubes in the same layer is constant, since the outer diameter of the heat exchange tubes 4 is gradually decreased toward the inner side 18 on the outer side 19, Not only the gap between the two heat exchange tubes adjacent to the outer side 19 of the serpentine spring-shaped heat exchange tube 4 is smaller than the gap between the adjacent two heat exchange tubes of the inner side 18, thereby allowing the outer side
  • the density of the heat exchange tubes 4 near 19 is greater than the density of the heat exchange tubes 4 on the inner side 18, while the heat exchange tubes 4 near the outer side 19 are larger than the heat exchange tubes of the inner side 18, so the outer side 19
  • the surface area of the heat exchange tube 4 is also larger than the surface area of the heat exchange tube 4 of the inner side 18, which is equivalent to further increasing the heat exchange area of the portion and improving the heat exchange efficiency.
  • the process of gradually decreasing the outer diameter of the heat exchange tube is also a process in which the inner diameter of the heat exchange tube is gradually reduced.
  • the heat exchange area of the low temperature liquid and the heat exchange tube flowing in the heat exchange tube near the outer side 19 can be made larger than the heat exchange area of the low temperature liquid and the heat exchange tube of the heat exchange tube near the inner side 18.
  • the heat exchange efficiency of the heat exchange tubes 4 on the outer side 19 through which the moist hot air mainly passes is further increased.
  • the surface area of the heat exchange tube near the outer side 19 and the heat exchange area of the inner low temperature liquid and the heat exchange tube are further increased to further improve the condensation effect of the condenser and improve the drying of the dryer.
  • the difference between the embodiment and the above embodiment is that the interlayer gap of the heat exchange tube 4 is fixed in the embodiment, and the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is fixed, and the outer diameter of the heat exchange tube is unchanged.
  • the inner diameter of the heat pipe gradually decreases from the outer side 19 to the inner side 18.
  • This design satisfies the application environment where the size of the condenser casing is required.
  • the outer casing specification of the condenser has a certain limit, by fixing the interlayer gap of the heat exchange tube 4, the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is fixed, and the heat exchange is performed.
  • the outer diameter of the tube is constant, and the inner diameter of the heat exchange tube is gradually reduced from the outer side 19 to the inner side 18, so that the heat exchange area of the low temperature liquid and the heat exchange tube flowing in the heat exchange tube near the outer side 19 can be made larger than The heat exchange area of the cryogenic liquid and the heat exchange tubes of the heat exchange tubes near the inner side 18. Further, the condensation efficiency of the outer side 19 of the condenser is also improved.
  • the difference between the embodiment and the above embodiment is that the interlayer gap of the heat exchange tube 4 in the embodiment is fixed, the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is fixed, and the outer diameter of the heat exchange tube is unchanged.
  • the inner diameter of the heat exchange tube gradually decreases from the lower layer to the upper layer.
  • the air inlet 8 connected to the air outlet of the outer cylinder 13 from the lower portion of the condenser 1 under the driving of the fan 15 enters the condenser 1.
  • the cooling water flows into the heat exchange tube 4 through the liquid inlet 6 at the upper portion of the condenser 1, and is discharged along the internal passage from the liquid discharge port 3 at the lower portion of the condenser 1, and the cooling water flows through the heat exchange tube 4 and is condensed.
  • the humid hot air flowing into the air inlet 8 of the device 1 is sufficiently heat exchanged.
  • the low temperature liquid in the heat transfer tubes 4 of the condenser 1 flows downward from the upper portion, and the moist hot air flows from the bottom to the top. This treatment is to carry out the heat exchange process more efficiently, but at the same time it also has room for improvement.
  • the heat exchange liquid in the heat exchange tube 4 is continuously exchanged with the hot humid air during the downward flow, and absorbs a large amount of heat; meanwhile, the lower heat exchange tube 4 is closer to the damp heat.
  • the air inlet port 8 of the air causes both the temperature of the heat exchange tube 4 at the lower portion of the condenser 1 to be higher than the temperature of the upper heat exchange tube 4. This will cause a significant drop in the condensation at the bottom of the condenser, which will generally reduce the condenser condensation.
  • the heat exchange tube design of the embodiment is adopted to fix the interlayer gap of the heat exchange tube 4, the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is fixed, the outer diameter of the heat exchange tube is constant, and the inner diameter of the heat exchange tube is The lower layer gradually decreases toward the upper layer.
  • This embodiment solves the problem that the condensation efficiency at the bottom of the condenser 1 is low.
  • the heat exchange in the heat exchange tube 4 at the bottom of the condenser 1 is achieved under the same external dimensions.
  • the heat exchange area between the medium and the heat exchange tube is larger than the heat exchange area between the heat exchange medium and the heat exchange tube in the upper heat exchange tube 4, and the condensation effect of the dryer of the washing and drying machine is improved, and the drying efficiency of the washing and drying machine is improved. .
  • the difference between this embodiment and the above embodiment is that the thickness of the heat exchange tube 4 in this embodiment is constant, the interlayer spacing of the center line of the tube is constant, and the pitch of the serpentine spring-shaped heat exchange tube 4 in the same layer is unchanged.
  • the outer diameter of the heat exchange tube gradually decreases from the lower layer to the upper layer.
  • the inner diameter of the bottom heat exchange tube 4 is increased, thereby increasing the heat exchange area between the bottom heat exchange medium and the heat exchange tube, and simultaneously increasing the heat exchange area of the bottom heat exchange tube 4. .
  • the purpose of enhancing the heat exchange efficiency of the bottom heat exchange tube 4 is achieved, and the disadvantages of the above-mentioned condensation efficiency reduction due to insufficient heat exchange capacity at the bottom are largely avoided.
  • the goal of improving the condensation effect of the dryer of the washing and drying machine and improving the drying efficiency of the washing and drying machine is achieved.
  • the interlayer spacing of the tube centerline is required to be constant, mainly for the reference requirement in the manufacture of such a heat exchange tube.
  • the method of changing the heat exchange area distribution of the heat exchange medium and the heat exchange tube in the heat exchange tube 4 can also be applied to more application scenarios at the same time. Let me repeat.
  • the upper portion of the heat exchange tube 4 has a shower box 7, which has a hollow cavity structure and a shower box at the top.
  • the water inlet 10 is connected to the water inlet pipe of the washing machine, and the bottom of the spray box 7 is a shower surface for opening a plurality of spray outlets 11.
  • the length of the shower box 7 is the same in the same direction as the top of the outer casing 5.
  • the present invention is provided with a spray box 7 on the upper portion of the heat exchange tube 4 for rinsing the wire dust adhering to the heat transfer tube 4.
  • the spray box 7 is provided with a shower box water inlet 10 for connecting the water inlet pipe, and a lower spray outlet 11 for discharging the flushing water flow to the heat exchange tube. The flushed lint is discharged from the condensate drain 2 .
  • the heat exchange tube in the form of the heat exchanger of the invention has a large contact area with air, and has many circuits for winding back and forth, so that a shower device with a large flow rate and a large coverage area can achieve the desired spray effect.
  • the length of the shower box is set to be the same as the width at the widest point of the condenser, which is the design adopted to increase the spray effect, and the generation of the spray dead angle is minimized.
  • the diameter of the spray outlet 11 is generally from 1 to 10 mm, preferably from 2 to 5 mm.
  • the shape of the spray outlet can also be set to a square shape, a rectangular shape or other shapes.
  • the actual spray effect can also be used to adjust the distribution density of the spray outlet 11 to achieve a more optimized effect.
  • the water flow is used to flush the wire scraps which may adhere to the heat exchange tubes, thereby not only avoiding the heat exchange efficiency caused by the accumulation of the wire chips, but also reducing the growth of the bacteria and making the internal environment of the washing and drying machine healthier. .
  • This embodiment discloses a washing machine having the high efficiency condenser described in any of Embodiments 1 to 6.
  • the washing machine of the embodiment successfully realizes the gas-liquid separation of the condensation process by using the high-efficiency condenser, overcomes the disadvantages of the existing condenser which directly condenses with the spray cold water, so that the heat exchange area in the heat exchange process is fixed and Controllable.
  • the washing machine in this embodiment uses a multi-layered serpentine-shaped heat exchange tube to increase the contact area between the heat exchange device and the moist hot air; and comprehensively adjusts the serpentine spring shape by combining the air flow direction in the internal cavity of the condenser.
  • the heat pipe's density and outer diameter and inner diameter are various ways to fully utilize the overall area of the heat exchanger, and greatly improve the heat exchange efficiency between the hot and humid air and the heat exchange tube.
  • a spray box is further disposed, and the spray box uses the water flow to flush the wire sticking on the heat exchange tube, thereby avoiding the heat transfer efficiency caused by the accumulation of the wire debris and the bacteria. Breeding not only improves heat exchange efficiency, shortens the overall drying time of the washing and drying machine, but also improves the hygienic environment of the washing and drying machine.

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  • Textile Engineering (AREA)
  • Detail Structures Of Washing Machines And Dryers (AREA)

Abstract

一种高效冷凝器(1)和具有该冷凝器(1)的洗衣机,所述冷凝器(1)为一种上宽下窄,并且下部向一侧弯曲的腔体结构,包括:外壳(5),下部开有进风口(8)与洗衣机外筒(13)相连,顶部开有出风口(9)与烘干风道(17)内的风机(15)相连;换热管(4),设置于外壳(5)内与湿热空气进行热交换,中空并且被弯折成多层结构,每层中的换热管(4)被弯折成蛇形弹簧形换热管(4),相邻两层换热管(4)间具有层间间隙;喷淋盒(7),设置于换热管(4)上方用于冲洗换热管(4)上的线屑;冷凝排水口(2),位于冷凝器(1)底部用于排出冷凝器(1)中的冷凝水与洗衣机排水管相连。本发明实现了冷凝过程的气液分离,并通过换热管(4)密度、外径和内径大小的变化的设置使换热更充分,冷凝效率提高,从而提高了洗干衣机的烘干效率。

Description

一种高效冷凝器和具有该冷凝器的洗衣机 技术领域
本发明属于洗干衣机领域,具体地说,涉及一种高效冷凝器和具有该冷凝器的洗衣机。
背景技术
市场上的洗干衣机大多数是利用电热来自动干燥衣物的清洁电器,对于空气湿度大,衣物不容易干的地区是重要的一种家用电器。洗干衣机根据结构形式分为滚筒式和柜式,以滚筒式居多。滚筒式干衣机一般由箱体、滚筒系统、热风系统、传动和控制系统组成;根据水分排出方式分为:排气型和除湿型,排气型是将机内水分蒸发形成的高温高湿空气直接排往机外,除湿型是将高温高湿空气经过热交换器生成冷凝水后再排往机外。
滚筒洗衣机的冷凝式烘干系统是在循环风道中设置冷凝器,干燥热风将湿衣物中的水分加热变为蒸汽,经过冷凝器时蒸汽冷却成流水排到洗衣机外部,冷凝后的干燥空气再经过风扇和加热器成为干燥热风,再次吹过衣物,直到把衣物中的水分全部变成蒸汽,然后该蒸汽再经过冷凝变成水排走,达到烘干目的。在这一过程中,起决定作用的是热风的温度和湿度。热风的温度取决于加热器的功率,他由纤维的耐热程度决定;热风的湿度即水蒸气含量,水蒸气变成蒸馏水的能力取决于冷凝器的冷凝能力,所以提高冷凝器的冷凝能力就提高了烘干效率。在现有技术中,一般采取如下两种方法:一是对冷凝器外壳以及热风管道外表实施风扇冷却或水喷淋冷却,二是在冷凝器内部或风道内部用散水降温。
中国专利CN200610000722.2公开了“一种用于高效烘干洗衣机干燥系统中的冷凝结构”包括一冷凝风道、冷凝水进水管,在所述的冷凝风道内固定设置至少一个冷凝装置:在所述的冷凝装置的一端设有与冷凝水进水管相连的、对冷凝装置进行冷却的冷凝水喷淋装置。在所述的冷凝装置的上方设有与冷凝水进水管相连的、便于冷凝水沿着冷凝板通过的冷凝水喷淋装置。
该发明没有实现冷凝过程的气液混合的问题,同时没有充分利用冷凝器内的空间,换热面积不能控制,并且利用不充分,同时还会将部分冷凝液重新带入到风循环系统中,降低干衣的效率。
中国专利CN 201410488762.0公开了“一种干衣机自清理过滤装置”包括冷凝器,过滤网,风道,储水盒,储水槽,排水泵,储水盒与排水泵之间设置上排水管,储水槽内设置水位传感器,还包括喷淋器,设置在风道内,位于过滤网与冷凝器中间,T排水管,用于连接 储水盒与喷淋器;第一传感器,位于风道内,感知过滤网上的线屑积累量;控制器,接收第一传感器和水位传感器传递的信号,分别发出指令控制排水泵和喷淋器的开启和关闭。
本发明喷淋器的位置位于过滤网和冷凝器中间,并设置了传感器,增加了设备的复杂性,并且当传感器出现故障时,该喷淋机构将无法正常运转。
有鉴于此特提出本发明。
发明内容
本发明要解决的技术问题在于克服现有技术的不足,提供一种高效冷凝器和具有该冷凝器的洗衣机,成功实现了冷凝过程的气液分离,并使换热介质间换热充分,冷凝效率提高,同时为冷凝器提供喷淋装置,冲洗线屑堆积,从而缩短洗干衣机的烘干时间。
为了实现该目的,本发明采用如下技术方案:
一种高效冷凝器,应用于洗干衣机,所述冷凝器为一种上宽下窄,并且下部向一侧弯曲的腔体结构,包括:
外壳,下部开有进风口与洗衣机外筒相连,顶部开有出风口与烘干风道内的风机相连,下部弯曲部的曲率半径小的一侧所在面为内边侧,曲率半径大的一侧所在面为外边侧;
换热管,设置于外壳内与湿热空气进行热交换,中空并且被弯折成多层结构,每层中的换热管被弯折成蛇形弹簧形换热管,相邻两层换热管间具有层间间隙;
喷淋盒,设置于换热管上方用于冲洗换热管上的线屑;
冷凝排水口,位于冷凝器底部用于排出冷凝器中的冷凝水与洗衣机排水管相连。
进一步地,所述换热管外径不变,换热管厚度不变,层间间隙不变,同层内蛇形弹簧形换热管的节距从外边侧向内边侧均逐渐增大。
进一步地,所述换热管厚度不变,换热管中心线的层间间距不变,同层内蛇形弹簧形换热管的节距不变,换热管外径从外边侧向内边侧均逐渐减小。
进一步地,所述换热管的层间间隙固定,同层内蛇形弹簧形换热管的节距固定,换热管外径不变,换热管内径从外边侧向内边侧均逐渐减小。
进一步地,所述换热管的层间间隙固定,同层内蛇形弹簧形换热管的节距固定,换热管外径不变,换热管内径从下层向上层逐渐减小。
进一步地,所述换热管厚度不变,管中心线的层间间距不变,同层内蛇形弹簧形换热管 的节距不变,换热管外径从下层向上层逐渐减小。
进一步地,所述换热管外径为2—15mm。
进一步地,所述换热管进液口位于冷凝器上端与低温液体管路相连,排液口位于冷凝器下端与高温液体管路相连。
进一步地,所述换热管上部具有喷淋盒,所述喷淋盒为中空的腔体结构,顶部具有一个进水口,底部为开有多个喷淋出水口的喷淋面。
进一步地,所述进水口与洗衣机的进水管路相连。
一种具有冷凝器的洗衣机,其具有以上任一所述特征的高效冷凝器。
采用上述技术方案后,本发明与现有技术相比具有以下有益效果。
本发明所揭示的一种高效冷凝器和具有该冷凝器的洗衣机,成功实现了冷凝过程的气液分离,克服了现有的用喷淋冷水直接进行冷凝的冷凝器的弊端,使得热交换过程中的换热面积固定并且可控。本发明中多层的蛇形弹簧形的换热管增加了换热装置和湿热空气的接触面积;通过结合冷凝器内部腔体中的空气流动方向,综合调整蛇形弹簧形换热管的疏密程度和外径和内径大小等多种方式,达到充分合理利用换热器整体面积,大幅度提高了湿热空气与换热管之间的换热效率。同时在本发明中换热管的上部还设置有喷淋盒,喷淋盒利用水流冲洗粘附在换热管上的线屑,避免由线屑堆积造成的换热效率下降和细菌滋生,不但提高了换热效率,缩短了洗干衣机的整体烘干时间而且还使洗干衣机的卫生环境得到了改善。
下面结合附图对本发明的具体实施方式作进一步详细的描述。
附图说明
附图作为本发明的一部分,用来提供对本发明的进一步的理解,本发明的示意性实施例及其说明用于解释本发明,但不构成对本发明的不当限定。显然,下面描述中的附图仅仅是一些实施例,对于本领域普通技术人员来说,在不付出创造性劳动的前提下,还可以根据这些附图获得其他附图。在附图中:
图1是使用本发明的洗干衣机部分剖视示意图;
图2是使用本发明的洗干衣机外形示意图;
图3是本发明冷凝器组件剖视示意图;
图4是本发明冷凝器组件示意图;
图5是本发明冷凝器的换热管示意图;
图6是本发明冷凝器的喷淋盒外观示意图;
图7是本发明冷凝器的喷淋盒剖切示意图。
图中:1、冷凝器;2、冷凝排水口;3、排液口;4、换热管;5、外壳;6、进液口;7、喷淋盒;8、进风口;9、出风口;10、喷淋盒进水口;11、喷淋出水口;12、门体;13、外筒;14、电机;15、风机;16、加热器;17、烘干风道;18、内边侧;19、外边侧。
需要说明的是,这些附图和文字描述并不旨在以任何方式限制本发明的构思范围,而是通过参考特定实施例为本领域技术人员说明本发明的概念。
具体实施方式
为使本发明实施例的目的、技术方案和优点更加清楚,下面将结合本发明实施例中的附图,对实施例中的技术方案进行清楚、完整地描述,以下实施例用于说明本发明,但不用来限制本发明的范围。
在本发明的描述中,需要说明的是,术语“上”、“下”、“前”、“后”、“左”、“右”、“竖直”、“内”、“外”等指示的方位或位置关系为基于附图所示的方位或位置关系,仅是为了便于描述本发明和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此不能理解为对本发明的限制。
在本发明的描述中,需要说明的是,除非另有明确的规定和限定,术语“安装”、“相连”、“连接”应做广义理解,例如,可以是固定连接,也可以是可拆卸连接,或一体地连接;可以是机械连接,也可以是电连接;可以是直接相连,也可以通过中间媒介间接相连。对于本领域的普通技术人员而言,可以具体情况理解上述术语在本发明中的具体含义。
如图1至图7所示,本发明公开了一种高效冷凝器和具有该冷凝器的洗衣机。所述冷凝器1为一种上宽下窄,并且下部向一侧弯曲的腔体结构,包括:外壳5,下部开有进风口8与洗衣机外筒13相连,顶部开有出风口9与烘干风道17内的风机15相连,下部弯曲部的曲率半径小的一侧所在面为内边侧18,曲率半径大的一侧所在面为外边侧19;换热管4,设置于外壳5内与湿热空气进行热交换,中空并且被弯折成多层结构,每层中的换热管被弯折成蛇形弹簧形换热管4,相邻两层换热管间具有层间间隙;喷淋盒7,设置于换热管4上方用于冲洗换热管4上的线屑;冷凝排水口2,位于冷凝器1底部用于排出冷凝器1中的冷凝水与洗衣机排水管相连。本发明实现了冷凝过程的气液分离,并通过换热管密度、外径和内径大 小变化的设置使换热更充分,冷凝效率提高,从而提高了洗干衣机的烘干效率。
实施例1
如图1至图5所示,本实施例中的高效冷凝器1应用于洗干衣机,冷凝器1为一种上宽下窄,并且下部向一侧弯曲的腔体结构,包括:
外壳5,下部开有进风口8与洗衣机外筒13相连,顶部开有出风口9与烘干风道17内的风机15相连,下部弯曲部的曲率半径小的一侧所在面为内边侧18,曲率半径大的一侧所在面为外边侧19;
换热管4,设置于外壳5内与湿热空气进行热交换,中空并且被弯折成多层结构,每层中的换热管被弯折成蛇形弹簧形换热管4,相邻两层换热管间具有层间间隙,所述换热管4的进液口6位于冷凝器1上端与低温液体管路相连,排液口3位于冷凝器1下端与高温液体管路相连,所述的低温管路和高温管路只是相对于换热前后的液体温度对比而言,并不代表绝对温度的意义;
喷淋盒7,设置于换热管4上方用于冲洗换热管4上的线屑;
冷凝排水口2,位于冷凝器1底部用于排出冷凝器1中的冷凝水与洗衣机排水管相连。
如图2所示,本实施例中使用本发明所述冷凝器的洗干衣机,包括外筒13、电机14、烘干风道17、风机15、冷凝器1组件等,风机15设置于烘干风道17前端,冷凝器1组件设置于风机15前端。如图1所示,洗干衣机烘干风道17内部设有加热器16。在烘干衣物时,首先利用加热器16加热空气,热空气被风机15驱动进入洗衣筒并把衣物上残留的水分加热成水蒸汽,水蒸汽随着热空气在风机15的驱动下进入冷凝器1,水蒸汽在冷凝器1里被冷凝成液态水通过冷凝器1底部的冷凝排水口2排走,相对干燥的空气再次经加热器16加热进入洗衣筒参与干衣循环。经过一定时间的循环过程,衣物即被烘干。
本实施例的冷凝器组件如图4所示,冷凝器组件包括冷凝器1、换热管4,喷淋盒7等。冷凝器1上部为出风口9,出风口9连接风机15进口,冷凝器1下部设有进风口8,进风口8连接外筒13出风口。冷凝器1底部设有冷凝排水口2,用于排出水蒸汽冷凝形成的液态水。喷淋盒7设于冷凝器1上部。如图3所示,换热管4被弯折成多层结构,每层中的换热管被弯折成蛇形弹簧形换热管4,相邻两层换热管间具有层间间隙,设置于冷凝器1内部的空腔中,冷却水经过进液口6流入换热管4内部并沿内部通路流经排液口3排走,冷却水在流经换热管4时与经冷凝器1进风口8流入的湿热气流充分换热,把湿热气流携带的水蒸汽冷凝 成液态水,液态水经冷凝排水口2流出冷凝器1然后排出机外。在整个的冷凝换热的过程中,冷凝器1的换热管4中的低温液体从上部向下流动,湿热空气从下向上流动,这样的布置可以提高换热的效率。
进一步地,如图5所示的换热管示意图,进液口6与排液口3分别设于其上、下两端。进液口6与洗干衣机的进水管相连,排液口3与洗干衣机的排水管相连,在一些具有蒸发器热循环的洗干衣机中,为了达到冷凝的效果,进液口6还可以和其他换热液体介质相连,达到在换热管4中充满了流动的低温液体的目的。
换热管4为多层结构,每层中的换热管被弯折成蛇形弹簧形换热管4,相邻两层换热管间具有层间间隙,所以具有很大的表面积,因此流经其内部的冷却水可以充分的与湿热气流换热,具有良好的冷凝效率。为了保证换热管的换热效率,本发明的换热管4材质采用铜、铜合金、铝、铝合金或其他导热性好的材料。换热管的外径一般取2-15mm,本实施例采用优选外径为4-8mm。
同时冷凝器1组件上部设有喷淋盒7,可以利用进水管流入的水流冲洗可能粘附在换热管上的线屑。本发明的换热管4为多层结构,每层中的换热管被弯折成蛇形弹簧形换热管4,相邻两层换热管间具有层间间隙,具有很大的表面积,因此冷水流经换热管4时可以与湿热气流充分换热,具有很高的冷凝效率。使用该冷凝方法的洗干衣机可以显著提高冷凝效率,大大缩短干衣时间,同时具有良好的节能效果。
本实施例中特别对于所述换热管4的分布特别采用了一种外径不变,换热管4厚度不变,层间间隙不变,同层内蛇形弹簧形换热管4的节距从外边侧19向内边侧18均逐渐增大的方式。采用这样的换热管4的分布方式使得换热管在外边侧19附近的换热管4密度大于内边侧18的换热管4的密度,并且这种变化是平滑过渡的。
采用这样的设计是为了更加有利于湿热空气在冷凝器1中的均匀流动,增加湿热空气和换热管4的接触时间和面积。在本发明中冷凝器1被设置为一种上宽下窄,并且下部向一侧弯曲的腔体结构。在这样的腔体结构中,湿热空气的流动并不是均匀的,即湿热空气在外边侧19的一边流动速度要远快于内边侧18一边的速度。这样造成的结果一方面是在相同的条件下冷凝器的外边侧19的换热管4需要进行更多的热量交换,使得外边侧的换热管4由于温度上升而使换热效率下降;另一方面,湿热空气由于大部分从外边侧19流动,造成内边侧18一侧的换热管换热不完全,没有充分利用换热管4的表面积,没有最大限度使用冷凝器1的冷凝能力。
因此用本实施例中的方式,即换热管4在外边侧19附近的换热管4密度大于内边侧18的换热管4的密度的方式,一方面增加了换热管4在外边侧19内单位面积内的换热介质的数量从而提高换热率,另一方面通过减小外边侧19的间隙的方式,也使湿热空气在冷凝器1中在外边侧19一侧流动时具有更大的风阻,使空气可以尽量在冷凝器1的腔体均匀流动,从而更好利用内边侧18部分的换热介质的目的。最终提高了冷凝器的冷凝效果,提高了干洗衣机的干衣效率。
实施例2
本实施例与实施例1的区别在于,所述换热管厚度不变,换热管中心线的层间间距不变,同层内蛇形弹簧形换热管4的节距不变,换热管外径从外边侧19向内边侧18均逐渐减小。
采用这样的换热管4的分布方式虽然同层内的蛇形弹簧形换热管的节距不变,但是由于换热管4的外径在外边侧19向内边侧18逐渐减小,不但使蛇形弹簧形换热管4在外边侧19附近相邻的两段换热管之间的间隙小于内边侧18的相邻的两段换热管之间的间隙,从而让外边侧19附近的换热管4密度大于内边侧18的换热管4的密度,同时外边侧19附近的换热管4由于外径要大于内边侧18的换热管,所以外边侧19的换热管4表面积也要大于内边侧18的换热管4的表面积,这样也就等于进一步增加了这部分的换热面积,提高了换热效率。同时由于保持了换热管厚度不变,因此在换热管外径逐渐变小的过程,也同样是换热管的内径逐渐变小的过程。这样可以同时使在外边侧19附近的换热管内流动的低温液体与换热管的换热面积大于在内边侧18附近的换热管的低温液体与换热管的换热面积。更加进一步提高在湿热空气主要经过的外边侧19的换热管4的换热效率。
这样在实施例1的原理基础上,进一步通过增加外边侧19附近换热管的表面积,和内部低温液体与换热管的换热面积,达到进一步提高冷凝器冷凝效果和提高洗干衣机干衣效率的目的。
实施例3
本实施例与上述实施例的区别在于,本实施例中换热管4的层间间隙固定,同层内蛇形弹簧形换热管4的节距固定,换热管外径不变,换热管内径从外边侧19向内边侧18均逐渐减小。
这样的设计满足对于冷凝器外壳尺寸有要求的应用环境。在冷凝器的外壳规格有一定限制的时候,通过让换热管4的层间间隙固定,同层内蛇形弹簧形换热管4的节距固定,换热 管外径不变,换热管内径从外边侧19向内边侧18均逐渐减小的方式,可以使在外边侧19附近的换热管内流动的低温液体与换热管的换热面积大于在内边侧18附近的换热管的低温液体与换热管的换热面积。进而同样使冷凝器的外边侧19的冷凝效率提高。
实施例4
本实施例与上述实施例的区别在于,本实施例中的换热管4的层间间隙固定,同层内蛇形弹簧形换热管4的节距固定,换热管外径不变,换热管内径从下层向上层逐渐减小。
如图1至图5所示,在烘干衣物时,利用加热器16加热空气,热空气被风机15驱动进入洗衣筒并把衣物上残留的水分加热成水蒸汽,水蒸汽随着热空气在风机15的驱动下从冷凝器1下部与外筒13出风口相连的进风口8,进入到冷凝器1中。同时,冷却水经过冷凝器1上部的进液口6流入换热管4内部并沿内部通路从冷凝器1下部的排液口3排走,冷却水在流经换热管4时与经冷凝器1进风口8流入的湿热气流充分换热。在整个的冷凝换热的过程中,冷凝器1的换热管4中的低温液体从上部向下流动,湿热空气从下向上流动。这样的处理是为了更高效地进行换热过程,但同时它也存在着改进的空间。
在这种交换的过程中,换热管4中的换热液体在向下流动的过程中在不断地和湿热空气进行热交换,吸收了大量的热量;同时,下部换热管4更加接近湿热空气的进风口8,这两种因素都造成了冷凝器1下部的换热管4的温度高于上部换热管4的温度的情况。这样就会造成冷凝器底部的冷凝效果大幅度下降,从而总体降低冷凝器的冷凝效果。而且由于底部冷凝效果不够,反而会使一部分从上部冷凝下来的冷凝水不能够从冷凝排水口2中排出,而是被搅动的湿热空气重新吹回到洗衣机中,降低洗干衣机的干衣效率。
采取本实施例的换热管设计,使换热管4的层间间隙固定,同层内蛇形弹簧形换热管4的节距固定,换热管外径不变,换热管内径从下层向上层逐渐减小。本实施例解决了冷凝器1底部冷凝效率低下的问题,通过改变换热管4的内径大小的不同分布,使得在同样的外观尺寸下,达到冷凝器1底部的换热管4内的换热介质与换热管的换热面积大于上部换热管4内的换热介质与换热管的换热面积,达到提高洗干衣机冷凝器冷凝效果,提高洗干衣机干衣效率的目标。
实施例5
本实施例与上述实施例的区别在于,本实施例中的换热管4厚度不变,管中心线的层间间距不变,同层内蛇形弹簧形换热管4的节距不变,换热管外径从下层向上层逐渐减小。
采取本实施例的换热管设计,不但增加了底部换热管4的内径,从而增加了底部换热介质与换热管的换热面积,也同时增加了底部换热管4的换热面积。进而达到增强底部换热管4换热效率的目的,更大程度上避免了上述由于底部换热能力不够而造成的冷凝效率下降的弊端。最终达到了提高洗干衣机冷凝器冷凝效果,提高洗干衣机干衣效率的目标。在本实施例中之所以需要管中心线的层间间距不变,主要是为了在制作安装这种换热管时的基准要求。当然这样的设计会使换热管的层间距从上到下逐渐减少,但这并不影响底部吹入的湿热空气可以顺畅地在冷凝器内流动,因为层间间隙的变化并不会增加竖直方向流动的空气的阻力,不会影响换热效率。
当然通过改变换热管4内径大小分布,达到改变换热管4内换热介质与换热管的换热面积分布的方法,也可以同样被同时运用到更多的的应用情境中,这里不再赘述。
实施例6
如图3,图4,图6和图7所示,本实施例中换热管4上部具有喷淋盒7,所述喷淋盒7为中空的腔体结构,顶部具有一个喷淋盒进水口10,该进水口10与洗衣机的进水管路相连,喷淋盒7的底部为为开有多个多个喷淋出水口11的喷淋面。喷淋盒7的长度于外壳5顶部同方向上的长度相同。
洗干衣机在洗涤、烘干过程中会有线屑从衣物上脱落下来,脱落的线屑会随循环气流到达冷凝器内的换热管处,并有部分线屑粘附在换热管上。为了解决线屑堆积问题,本发明在换热管4上部设有喷淋盒7,用于冲洗粘附在换热管4上的线屑。喷淋盒7上端设有喷淋盒进水口10,用于连接进水管路,下端设有若干喷淋出水口11,用于向换热管喷出冲洗水流。冲洗下来的线屑从冷凝排水口2排出。本发明的换热器形式的换热管与空气接触面积较大,并且迂回盘旋的回路很多,因此需要大流量且覆盖面积大的喷淋设备才可以达到理想的喷淋效果。本实施例中将喷淋盒的长度设置为与冷凝器最宽处的宽度相同就是为了增加喷淋效果而采取的这种设计,最大限度地避免喷淋死角的产生。
喷淋出水口11的孔径一般取1-10mm,优选孔径为2-5mm。喷淋出水口的形状也可以设置成方形、矩形或其他形状,当然还可以通过实际的喷淋效果,对喷淋出水口11的分布密度调整也可以达到更加优化的效果。
本实施例利用水流冲洗可能粘附在换热管上的线屑,不但避免了因线屑堆积而造成的换热效率下降,同时还减少了细菌滋生,让洗干衣机的内部环境更健康。
实施例7
本实施例揭示一种洗衣机,具有上述实施例1—实施例6任一所述的高效冷凝器。本实施例的洗衣机,利用高效冷凝器,成功实现了冷凝过程的气液分离,克服了现有的用喷淋冷水直接进行冷凝的冷凝器的弊端,使得热交换过程中的换热面积固定并且可控。本实施例中的洗衣机使用多层的蛇形弹簧形的换热管增加了换热装置和湿热空气的接触面积;通过结合冷凝器内部腔体中的空气流动方向,综合调整蛇形弹簧形换热管的疏密程度和外径和内径大小等多种方式,达到充分合理利用换热器整体面积,大幅度提高了湿热空气与换热管之间的换热效率。同时在本实施例洗衣机使用的换热管的上部还设置有喷淋盒,喷淋盒利用水流冲洗粘附在换热管上的线屑,避免由线屑堆积造成的换热效率下降和细菌滋生,不但提高了换热效率,缩短了洗干衣机的整体烘干时间而且还使洗干衣机的卫生环境得到了改善。
以上所述仅是本发明的较佳实施例而已,并非对本发明作任何形式上的限制,虽然本发明已以较佳实施例揭露如上,然而并非用以限定本发明,任何熟悉本专利的技术人员在不脱离本发明技术方案范围内,当可利用上述提示的技术内容作出些许更动或修饰为等同变化的等效实施例,但凡是未脱离本发明技术方案的内容,依据本发明的技术实质对以上实施例所作的任何简单修改、等同变化与修饰,均仍属于本发明方案的范围内。

Claims (10)

  1. 一种高效冷凝器,应用于洗干衣机,其特征在于:所述冷凝器为一种上宽下窄,并且下部向一侧弯曲的腔体结构,包括:
    外壳,下部开有进风口与洗衣机外筒相连,顶部开有出风口与烘干风道内的风机相连,下部弯曲部的曲率半径小的一侧所在面为内边侧,曲率半径大的一侧所在面为外边侧;
    换热管,设置于外壳内与湿热空气进行热交换,中空并且被弯折成多层结构,每层中的换热管被弯折成蛇形弹簧形换热管,相邻两层换热管间具有层间间隙;
    喷淋盒,设置于换热管上方用于冲洗换热管上的线屑;
    冷凝排水口,位于冷凝器底部用于排出冷凝器中的冷凝水与洗衣机排水管相连。
  2. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管外径不变,换热管厚度不变,层间间隙不变,同层内蛇形弹簧形换热管的节距从外边侧向内边侧均逐渐增大。
  3. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管厚度不变,换热管中心线的层间间距不变,同层内蛇形弹簧形换热管的节距不变,换热管外径从外边侧向内边侧均逐渐减小。
  4. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管的层间间隙固定,同层内蛇形弹簧形换热管的节距固定,换热管外径不变,换热管内径从外边侧向内边侧均逐渐减小。
  5. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管的层间间隙固定,同层内蛇形弹簧形换热管的节距固定,换热管外径不变,换热管内径从下层向上层逐渐减小。
  6. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管厚度不变,管中心线的层间间距不变,同层内蛇形弹簧形换热管的节距不变,换热管外径从下层向上层逐渐减小。
  7. 根据权利要求1-6任一项所述的高效冷凝器,其特征在于:所述换热管外径为2—15mm。
  8. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管进液口位于冷凝器上端与低温液体管路相连,排液口位于冷凝器下端与高温液体管路相连。
  9. 根据权利要求1所述的高效冷凝器,其特征在于:所述换热管上部具有喷淋盒,所述喷淋盒为中空的腔体结构,顶部具有一个进水口,底部为开有多个喷淋出水口的喷淋面。
  10. 一种具有冷凝器的洗衣机,其特征在于:使用权利要求1-9任一所述特征的高效冷凝器。
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