JP2015525618A - Dry cleaning device with cooling mechanism and compatible with multiple solvents - Google Patents

Abstract

A dry cleaning apparatus having a washing process, a drying process, and a cooling mechanism includes a rotating drum for storing clothes and other laundry, a first solvent and a first solvent tank for the first washing process, a second A second solvent or second solvent tank for the washing process, a first water separator operatively connected to the first solvent tank, a second water separator operatively connected to the second solvent tank, one end of the first and first water separators A solvent recovery mechanism is provided that is operatively connected to the two water separators and further operatively connected to the rotating drum. The cooling mechanism of the apparatus includes a first heat exchange unit, a second heat exchange unit, a cooling tank that stores the refrigerant, and a blower that cools the refrigerant. In this dry cleaning apparatus, different solvents can be used independently in each washing process in the same apparatus without changing the solvent or washing the apparatus. [Selection] Figure 1

Description

  The present invention relates to a dry cleaning apparatus that uses a cooling mechanism in a drying process.

  Early dry cleaning devices were only wash extractors that used dry cleaning solvents instead of water and independent steam heated and water cooled dryers. This apparatus has a great influence on the environment because the dry cleaning solvent evaporated in the course of the drying process is discharged into the atmosphere without being condensed again.

  The next released dry cleaning device uses a system that evaporates the dry cleaning solvent and the evaporated solvent returns to the liquid through the cooling coil to condense and collect a considerable amount of the evaporated solvent in the device. I was able to.

  The next developed dry cleaning technology has a drying function in an apparatus used as a laundry dehydrator. This system was sufficiently effective when perchlorethylene (hereinafter also referred to as “perc”) solvent was used, but a large amount of the solvent was still released into the atmosphere.

  In order to improve the recovery amount of the dry cleaning solvent, a cooling function was added to the device, and more solvent can be recovered by cooling the solvent vapor. However, such devices have disappeared as US federal and local agencies have announced that "perc" gas is harmful.

  An alternative solvent that has been put on the market is a hydrocarbon solvent, or a mixture thereof, which requires more time for washing and is more difficult to dry. The industry tried to use similar technology that was available at the time, but it took more time to wash and dry.

  Other traditional dry cleaning devices have used a highly efficient air-cooled heat pump system, but have drawbacks. Since the air cannot be cooled when the ambient temperature in the dry cleaning factory becomes high, the apparatus easily overheats, and the drying process takes a long time to match the temperature at which the heat pump system can operate.

  Traditional dry cleaning has been designed to use a single solvent, although the amount of laundry may require the use of multiple solvents. For example, it is preferable to use a general hydrocarbon solvent for leather or metal bead garments and clothing that easily deposits color.

  However, dirty clothing requires a stronger solvent. To change the solvent, the solvent tank and other parts must be washed directly by hand to avoid mixing with the solvent already used, and the user is exposed to the solvent's toxic gas in the process of changing the solvent There was a possibility. When using one dry cleaning system, the solvent must be changed directly by hand, so two dry cleaning devices can often be used separately, one with a strong solvent and the other with a weak solvent. It was.

  For these reasons, there is a need for new dry cleaning devices that overcome the shortcomings of traditional devices.

  A dry cleaning apparatus having a washing process and a drying process according to the present invention includes a rotating drum for storing laundry, a first solvent tank for containing a first solvent, a second solvent tank for containing a second solvent, and a first solvent. A first water separator operatively connected to the tank, a second water separator operatively connected to the second solvent tank, and a solvent recovery mechanism operatively connected to the first and second water separators and the rotating drum. Prepare.

  The solvent recovery mechanism includes a cooling mechanism having a first heat exchange unit, a second heat exchange unit, a cooling tank for storing the refrigerant, and a blower for cooling the refrigerant.

  In the washing process, only one of the first and second solvent tanks is used in one process, and the solvent used in the washing process is evaporated in the drying process using heated air. In this dry cleaning apparatus, the first or second solvent can be used separately in the same apparatus, and it is not necessary to replace the solvent or clean the apparatus.

  The first heat exchange unit heats the air used in the drying process, and the second heat exchange unit cools and condenses the evaporated solvent using the heated air. When the condensed solvent is the first solvent, the solvent passes through the first water separator from which water is separated and is collected in the first solvent tank. When the condensed solvent is the second solvent, the solvent passes through the second water separator and is collected in the second solvent tank.

  A dry cleaning apparatus having another washing process and drying process according to the present invention is operatively connected to a rotating drum, a first solvent, a first solvent tank for storing the first solvent, and a first solvent tank. The first water separator, the second solvent, the second solvent tank for storing the second solvent, the second water separator operatively connected to the second solvent tank, the first water separator and the rotation A first solvent recovery mechanism operatively connected to the drum, a second solvent recovery mechanism operatively connected to the second water separator and the rotating drum, and a cooling mechanism. The cooling mechanism includes a first heat exchange unit, a second heat exchange unit, a third heat exchange unit, a fourth heat exchange unit, a refrigerant tank for storing the refrigerant, and a blower for cooling the refrigerant. Have

  In the washing process, only one of the first and second solvents is used in one process, and the first or second solvent used in the washing process is evaporated in the drying process using heated air. .

  When the first solvent is used in the washing process, the air used in the drying process is heated in the first heat exchange unit, and the first solvent is evaporated using the air heated in the first heat exchange unit. The solvent is cooled and condensed in the second heat exchange section. When the second solvent is used in the washing process, the second solvent is heated by the third heat exchanging unit and is evaporated using the air heated in the third heat exchanging unit. Is cooled and condensed in the fourth heat exchange section. The first or second solvent passes through the first or second water separator, respectively, and is recovered in the tank of the first or second solvent.

  The dry cleaning apparatus can use the first and second solvents independently, and can minimize the possibility of mixing with other solvents.

  A dry cleaning apparatus having another washing process and a drying process according to the present invention includes a rotating drum, a first solvent tank for storing a first solvent, a first water separator operatively connected to the first solvent tank, A second solvent tank for storing the second solvent; a second water separator operatively connected to the second solvent tank; a third solvent tank for storing the third solvent; and a third solvent tank connected to the third solvent tank. A water separator, a first solvent recovery mechanism operatively connected to the first and second water separators and the rotating drum, and a second solvent recovery mechanism operatively connected to the third water separator, the rotating drum and the cooling mechanism. With. The cooling mechanism includes a first heat exchange unit, a second heat exchange unit, a third heat exchange unit, a fourth heat exchange unit, a refrigerant tank for storing the refrigerant, and a blower for cooling the refrigerant. Have In the washing process, only one of the first, second, and third solvents can be used, and in the drying process, the solvent used in the washing process can be evaporated using heated air. .

  When the first or second solvent is used in the washing cycle, the first heat exchange unit heats air used in the drying process. The solvent evaporated using the air heated in the first heat exchange unit is cooled and condensed in the second heat exchange unit. When the third solvent is used in the washing process, the third heat exchange unit heats the air used in the drying process. The fourth heat exchange unit cools and condenses the solvent evaporated using the air heated by the third heat exchange unit.

  The condensed first, second, or third solvent passes through the first, second, or third water separator, respectively, and is collected in the first, second, or third solvent tank, and then in the apparatus. An independent and separate solvent circuit is formed.

  In another embodiment, the dry cleaning apparatus may include a temperature raising device that heats air used in the drying process. Steam supplied from an external boiler can be used as a heat source for the temperature raising device. However, in other embodiments according to the present invention, a separate heater can be provided internally to supply heat to the temperature riser. The heater inside this can be an electric heater or a small boiler.

  In one embodiment, the dry cleaning apparatus includes a refrigerant cooling mechanism that cools the tank to prevent the apparatus from stopping when the refrigerant tank reaches a predetermined temperature. The refrigerant cooling mechanism can be set to turn off the system when the refrigerant tank reaches another predetermined temperature. In addition, the temperature of a refrigerant tank means the temperature of a tank or the temperature of the refrigerant | coolant which came out of the tank.

  The temperature can be about 70-100 ° F., preferably 80-90 ° F. The refrigerant cooling mechanism includes a refrigerant tank that stores the refrigerant, and the refrigerant is used to cool the refrigerant tank.

  When the refrigerant can be sufficiently cooled by the blower, the cooling mechanism can be cooled by the refrigerant.

  The following figures illustrate preferred embodiments of the present invention. Although parts and structures widely used in a general dry cleaning apparatus are not shown, those skilled in the art can easily understand the embodiments of the present invention without these illustrations.

It is one Embodiment concerning this invention, and is a schematic diagram of a dry cleaning device provided with two solvent tanks and one solvent recovery mechanism. It is other embodiment concerning this invention, and is a schematic diagram of the dry cleaning apparatus provided with two solvent tanks and two solvent collection | recovery mechanisms. FIG. 6 is a schematic view of a dry cleaning apparatus including three solvent tanks and two solvent recovery mechanisms according to another embodiment of the present invention. It is the schematic of the cooling mechanism of one Embodiment concerning this invention. It is the schematic of the cooling mechanism of other embodiment concerning this invention.

  FIG. 1 shows a dry cleaning apparatus according to an embodiment of the present invention. The dry cleaning apparatus includes a solvent recovery mechanism 100, a rotating drum 300 that stores laundry to be dry cleaned, two solvent tanks 601 and 602 that store other solvents, and two water separators 401 and 402, respectively. And two separation pumps 701 and 702, at least two filter systems 201 and 202, and a button trap 500. After the laundry is put into the rotating drum, the solvent is supplied to the drum from the solvent tanks 601 and 602 according to the user's selection or setting.

  If the first solvent in tank 601 is selected, pump 701 is activated to move the solvent from the solvent tank to filter section 201. In this filter section, solvent impurities such as color dyes are filtered.

  The position of the pump shown in the figure is for explanation, and can be arranged at a position more suitable for the operation of the dry cleaning device.

  The drum 300 is operatively connected to the solvent recovery mechanism 100, whereby air heated by the solvent recovery mechanism circulates to the drum, and solvent evaporated from the drum by the heated air circulates to the solvent recovery mechanism, and solvent recovery. The mechanism condenses and recovers the solvent.

  The drum 300 can be equipped with a button trap 500 as needed, which can keep heavy impurities such as buttons during the washing process.

  The solvent recovery mechanism 100 is operatively connected to two water separators 401 and 402, respectively. These water separators are operatively connected to two solvent tanks 601 and 602.

  The solvent recovery mechanism 100 includes a cooling mechanism having two independent heat exchange units. One heat exchange section is for heating air used in the drying process, and the other heat exchange section is for cooling and condensing the solvent evaporated in the drying process for solvent recovery. FIG. 1 does not show the cooling mechanism.

  The two solvents stored in the solvent tanks 601 and 602 circulate through two independent paths, but the two solvents circulate together in common parts such as a rotating drum, a solvent recovery mechanism, and a button trap. Therefore, a small amount of residual solvent used in the drying process may come into contact with the solvent used in another drying process.

  Thus, the above system is more suitable when a small amount of solvent does not affect the operation and management of the dry cleaning apparatus. For example, solvents having the same chemical composition but different concentrations can be used. In addition, even when different types of solvents are chemically similar, the amount of the first solvent mixed in the second solvent does not affect the dry cleaning operation using the second solvent, Even in certain cases where the use of the solvent in other dry cleaning operations is not affected, other solvents with different chemical components can be used.

  However, the specific solvent is preferably completely separated in each dry cleaning step, and in such a case, the dry cleaning apparatus shown in FIG. 2 is more suitable.

  The dry cleaning device of FIG. 2 is similar in that the solvent tank, water separator, pump, and filter system are all separated into two, but this device has two independent solvent recovery mechanisms 101, 102. These recovery mechanisms are coupled to two independent solvent tanks 601, 602, water separators 401, 402, pumps 701, 702, and filter systems 201, 202.

  The two solvent recovery mechanisms may have two independent cooling mechanisms, but may share one cooling mechanism and include an extra heat exchange unit. For example, the cooling mechanism can include one cooling tank and one blower, but can also include two independent heat exchangers for using two different solvents.

  In another alternative method, the cooling mechanism can include only one heat exchange section. In this case, the two solvent recovery mechanisms can each have two independent chambers located near the same heat exchanging unit, and can heat the air or condense the solvent by the same heat exchanging unit. . For example, the solvent recovery mechanism includes a spiral chamber that can be fabricated to surround the same heat exchanger.

  Accordingly, the embodiment including a plurality of heat exchange units for the purpose of heating and cooling can also include only one or a smaller number of heat exchange units than the above, and can repeatedly provide functions corresponding to the number of heat exchange units. .

  Various solvents are used in the dry cleaning apparatus. Hydrocarbon solvents and silicon solvents are exemplified, but solvents other than these may be used.

  The dry cleaning apparatus shown in FIG. 3 includes three solvent tanks 603, 604, and 605, but includes two solvent recovery mechanisms 103 and 104. In this embodiment, the solvent recovery mechanism 104 is dedicated to the solvent tank 605, and the solvent recovery mechanism 103 is operatively connected to the solvent tanks 603 and 604. This dry cleaning apparatus comprises three filter systems 203, 204, 205, which are each connected to three solvent tanks.

  The three solvent tanks can include two independent cooling mechanisms. However, as shown in FIG. 2, the three solvent tanks can share one cooling mechanism and include an extra heat exchange unit.

  As shown in FIG. 4, the refrigerant tank 1 stores the refrigerant, the refrigerant is cooled by the blower 9, and the blower 9 circulates air by the air compressor 6. The refrigerant compressor 5 compresses the refrigerant when the temperature of the refrigerant increases. The heated and compressed refrigerant is supplied to the heat exchange unit 4 to heat the air used in the drying process. Moreover, in another heat exchange part 3, ambient temperature is reduced by evaporation of a refrigerant | coolant. The solvent evaporated in the drying process moves to the heat exchange unit 3 and condenses. The refrigerant also evaporates in the evaporator 2, and the evaporator 2 can be used to lower the temperature of the solvent stored in the solvent tank or the solvent used in the washing process.

  Only the blower 9 may not cool the refrigerant sufficiently quickly, and the temperature of the refrigerant tank may rise. When the temperature of the refrigerant tank reaches the critical temperature, the operation of the entire cooling mechanism is stopped. Therefore, a refrigerant cooling mechanism can be provided around the refrigerant tank 1 in order to prevent the temperature of the cooling tank from rising above the critical temperature.

  A refrigerant for cooling the tank or a dry cleaning solvent can be used for the refrigerant cooling mechanism. The refrigerant can be stored in independent refrigerant tanks 38, 38a. The refrigerant in FIG. 5 can be cooled by the evaporator 2a.

  Although water can be used as the refrigerant, an independent water tank is not necessary in this case, and water can be supplied from an external water supply source.

  The refrigerant cooling mechanism can be set to operate when a predetermined temperature is reached. The temperature in this case is preferably about 70-100 ° F., particularly 80-90 ° F.

  The heated air used in the drying process can be further heated by the heating device 7. The thermal energy for heating the air by the heating device can be supplied by the above from the external supply source shown in FIG.

  As shown in FIG. 4, the dry cleaning apparatus has an internal heating source 10 for a heating device such as an electric heater. The heater can directly heat the temperature raising device or supply high temperature steam to heat the temperature raising device.

  The “solvent” in the present specification means a single solvent or a mixture of two or more solvents. In addition, the “other solvent” in the present specification means that the concentration or chemical component, or both are different.

  Although several embodiments of the present invention have been described above, the technical scope described in the claims is not limited thereto, and those skilled in the art within the scope not exceeding the technical idea of the present application. Includes all the possible variations, substitutions, additions and sub-combinations.

Claims (20)

A dry cleaning apparatus having a washing process and a drying process,
A rotating drum,
A first solvent tank for storing the first solvent;
A first water separator operatively connected to the first solvent tank;
A second solvent tank for storing the second solvent;
A second water separator operatively connected to the second solvent tank;
The first water separator and the second water separator, and a solvent recovery mechanism operatively connected to the rotating drum,
The solvent recovery mechanism includes a cooling mechanism,
The cooling mechanism includes a first heat exchange unit, a second heat exchange unit, a refrigerant tank for storing the refrigerant, and a blower for cooling the refrigerant,
Using one of the first solvent and the second solvent at a time in the washing step, evaporating the solvent used in the washing step in the drying step with heated air,
The air used in the drying step is heated in the first heat exchange unit, and the solvent evaporated by the heated air is cooled and condensed in the second heat exchange unit,
When the condensed solvent is a first solvent, the solvent is recovered in the first solvent tank via the first water separator, and when the condensed solvent is a second solvent, the solvent is A dry cleaning device that is recovered in the second solvent tank through a second water separator.   The dry cleaning apparatus according to claim 1, further comprising a heater that heats air used in the drying step.   The dry cleaning apparatus according to claim 2, further comprising an electric heater that supplies thermal energy to the temperature raising device.   The dry cleaning apparatus according to claim 2, wherein thermal energy is supplied to the temperature raising device by steam from an external heat supply source. A refrigerant cooling mechanism,
The dry cleaning apparatus according to claim 1, wherein the refrigerant cooling mechanism is activated when a temperature of the refrigerant tank reaches a predetermined temperature.   The dry cleaning apparatus according to claim 5, wherein the temperature is about 70 to 100 ° F. A refrigerant tank for storing the refrigerant;
The dry cleaning apparatus according to claim 5, wherein the cooling mechanism cools the refrigerant tank using the refrigerant. A dry cleaning apparatus having a washing process and a drying process,
A rotating drum,
A first solvent tank for storing the first solvent;
A first water separator operatively connected to the first solvent tank;
A second solvent tank for storing the second solvent;
A second water separator operatively connected to the second solvent tank;
A first solvent recovery mechanism operatively connected to the first water separator and the rotating drum;
A second solvent recovery mechanism operatively connected to the second water separator and the rotating drum;
A cooling mechanism,
The cooling mechanism includes a first heat exchange unit, a second heat exchange unit, a third heat exchange unit, a fourth heat exchange unit, a refrigerant tank for storing the refrigerant, and a blower for cooling the refrigerant. And having
Using one of the first solvent and the second solvent at a time in the washing step, evaporating the solvent used in the washing step in the drying step with heated air,
The first heat exchange unit heats air in the drying step when the first solvent is used in the washing step,
The second heat exchange unit cools and condenses the first solvent with air heated by the first heat exchange unit,
The third heat exchange unit heats air in the drying step when the second solvent is used in the washing step,
The fourth heat exchange unit cools and condenses the second solvent by the air heated by the third heat exchange unit,
The dry cleaning apparatus in which the first solvent or the second solvent is collected in the first solvent tank or the second solvent tank through the water separator first or second water separator, respectively.   The dry cleaning apparatus according to claim 8, further comprising a heater that heats air used in the drying step.   The dry cleaning apparatus according to claim 9, further comprising an electric heater that supplies thermal energy to the temperature raising device.   The dry cleaning apparatus according to claim 10, wherein thermal energy is supplied to the temperature raising device by steam from an external heat supply source. A refrigerant cooling mechanism,
The dry cleaning apparatus according to claim 8, wherein the refrigerant cooling mechanism is activated when a temperature of the refrigerant tank reaches a predetermined temperature.   The dry cleaning apparatus of claim 12, wherein the temperature is about 70-100 ° F.   The dry cleaning apparatus according to claim 8, wherein the first solvent is a hydrocarbon solvent, and the second solvent is a silicon solvent. A third solvent tank for accommodating the third solvent and the third water separator;
The dry cleaning apparatus according to claim 8, wherein the third water separator is operatively connected to the first solvent recovery mechanism and the third solvent tank. A dry cleaning apparatus having a washing process and a drying process,
A rotating drum,
A first solvent tank for storing the first solvent;
A first water separator operatively connected to the first solvent tank;
A second solvent tank for storing the second solvent;
A second water separator operatively connected to the second solvent tank;
A third solvent tank for storing the second solvent;
A third water separator operatively connected to the third solvent tank;
The first water separator and the second water separator, and a first solvent recovery mechanism operatively connected to the rotating drum;
A second solvent recovery mechanism operatively connected to the third water separator and the rotating drum;
A cooling mechanism,
The cooling mechanism includes a first heat exchange unit, a second heat exchange unit, a third heat exchange unit, a fourth heat exchange unit, a refrigerant tank for storing the refrigerant, and a blower for cooling the refrigerant. And having
Using one of the first solvent and the second solvent at a time in the washing step, evaporating the solvent used in the washing step in the drying step with heated air,
The first heat exchange unit heats air in the drying step when the first solvent or the second solvent is used in the washing step,
The second heat exchange unit cools and condenses the solvent using air heated by the first heat exchange unit,
The third heat exchange unit heats air in the drying step when a third solvent is used in the washing step,
The fourth heat exchange unit cools and condenses the third solvent using the air heated by the third heat exchange unit,
The condensed first solvent, second solvent, or third solvent passes through the first water separator, the second water separator, or the third water separator, respectively, and then passes through the first solvent tank, the second solvent, and the second solvent. A dry cleaning device recovered in a tank or a third solvent tank.   The dry cleaning apparatus according to claim 16, further comprising a heater that heats air used in the drying step.   The dry cleaning apparatus according to claim 17, further comprising an electric heater that supplies thermal energy to the temperature raising device. A refrigerant cooling mechanism,
The dry cleaning apparatus according to claim 16, wherein the refrigerant cooling mechanism is activated when a temperature of the refrigerant tank reaches a predetermined temperature.   The dry cleaning apparatus according to claim 16, wherein the first solvent and the second solvent are hydrocarbon solvents, and the third solvent is a silicon solvent.

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