JP4514683B2 - Dry cleaner - Google Patents

Description

  The present invention relates to a dry cleaner that is a washing machine for performing dry cleaning, and more particularly, to a pass / fail judgment of a temperature detection element that detects a drum inlet temperature during a drying operation.

In dry cleaning, clothes are generally dried by washing clothes using a petroleum-based solvent, draining the solvent from the washed clothes, and further evaporating and removing the solvent from the clothes.
A dry cleaner for performing such dry cleaning is provided with a drum for storing laundry and drying laundry after washing. The drum is provided with an inlet and an outlet for drying air. At the inlet, temperature detecting means (for example, a thermistor) for detecting the temperature of the drying air supplied into the drum during the drying process, and overheating A temperature sensitive element (for example, a thermostat) is provided as a prevention means.

In the dry cleaner, the temperature of the drying air introduced into the drum is controlled based on the temperature detected by the thermistor during the drying process, and when the drying air reaches a predetermined high temperature, the thermostat detects it. It is customary to have a double safety structure that works.
Patent Document 1 discloses a configuration in which a thermistor and a thermostat are provided at an air inlet of a drum in a clothes dryer for dry cleaning, and whether or not the thermostat functions normally.
JP 2000-51590 A

  As described in Patent Document 1, in the case of a dry cleaner that recovers all of the solvent, rather than a method that dries clothes by introducing outside air in the latter half of the drying process, whether or not the overheat prevention means that is a safety device is normal In order to check this, it is necessary to forcibly raise the temperature of the dry air at the drum inlet, and it is difficult to raise the temperature until the overheat prevention means operates every time the drying process is performed. This is because the air in the drum is not discharged to the outside but is circulated through the circulation path, and the circulation path is provided with a cooler for liquefying and recovering the vaporized solvent. Since the air cooled by the cooler is, for example, as low as about 10 ° C., it is difficult to raise the air to a temperature at which the overheat prevention means operates. Or there was the subject that it took time to raise.

If the cooler is not operated, the temperature of the circulating air does not decrease, but the concentration of the vaporized solvent in the air increases, which is problematic in terms of safety.
In this way, in the dry cleaner that recovers all the solvent, whether or not the overheat prevention means as a safety device that operates when the temperature of the dry air supplied to the drum rises excessively is determined each time. It was difficult to check in the drying process.

The present invention has been made based on such a background, and has as its main object to provide a dry cleaner that can reliably determine the quality of the overheat prevention means provided at the drum inlet at every drying step. To do .

  The invention described in claim 1 has an air inlet and an outlet, and is connected between a drum for drying laundry after being washed using a predetermined solvent, and an air outlet and an inlet of the drum. A circulation path, air blowing means for discharging the air in the drum from the outlet and circulating it from the inlet to the drum through the circulation path, and heating for heating the air sent from the inlet of the drum to the drum Means, a solvent recovery means for liquefying and recovering the solvent by cooling the air containing the vaporized solvent sent in the circulation path and provided in the circulation path, and provided at the inlet of the drum, An inlet temperature detecting means for detecting the temperature of the air entering the drum, and an overheat preventing means provided at the inlet of the drum and detecting that the temperature of the air entering the drum has reached a predetermined overheating temperature. And the heating means, the blowing means and the solvent recovery means are operated, the heated air is sent into the drum, the solvent contained in the laundry is vaporized with the heated air, and the air containing the evaporated solvent is circulated from the outlet to the circulation path. And a drying process execution means for performing a drying process in which air is cooled in a circulation path to liquefy and recover the solvent, and in the drying process, the amount of air blown from the air blowing means is reduced and the heating means is heated. Check that the inlet temperature detecting means continuously detects a predetermined temperature or higher for a certain period of time and determines whether the overheat preventing means is activated or not by determining whether the overheat preventing means is activated. A dry cleaner characterized by comprising:

The invention according to claim 2 is the dry cleaner according to claim 1, wherein the check means performs the determination during a predetermined time until the drying process is completed.
According to a third aspect of the present invention, the blower means includes a blower fan provided in the circulation path, a motor for rotating the blower fan, and an inverter for frequency-controlling the rotational speed of the motor. 3. The dry cleaner according to claim 2, wherein the check means lowers the frequency of the inverter to lower the rotational speed of the motor and lowers the amount of blown air.

According to a fourth aspect of the present invention, the heating means includes a heater pipe disposed at the inlet of the drum, a steam supply path for supplying steam to the heater pipe, and a valve for opening and closing the steam supply path. The dry cleaner according to any one of claims 1 to 3, wherein the check means fully opens the valve of the steam supply path.
The invention according to claim 5 is the dry cleaner according to claim 4, wherein the check means closes the valve of the steam supply path immediately after determining that the overheat prevention means is good. .

The invention according to claim 6 is characterized in that the inlet temperature detecting means includes a thermistor, and the overheat preventing means includes a thermistor and a transistor circuit which operates in response to detection of a predetermined temperature by the thermistor. A dry cleaner according to any one of claims 1 to 5 .

  According to the first aspect of the invention, every time the drying process is performed, the operation of the overheat prevention means can be surely checked, and the quality can be determined. Further, since the operation of the overheat prevention means can be checked in a short time, it is possible to minimize the rise of the temperature of the laundry in the drum above the preset drying temperature without taking the original drying time. . Thereby, shrinkage and breakage of the laundry (clothing) can be prevented. Further, the energy for heating the heating means can be minimized.

In the invention according to claim 2, the operation check of the overheat prevention means is performed at the end of the drying process. Since the concentration of the vaporized solvent contained in the air is low at the end of the drying process, the operation efficiency of the solvent recovery means and the heating means is good, and the quality determination of the overheat prevention means can be performed reliably in a shorter time.
In the invention according to claim 3, since the air volume of the air blowing means can be controlled to a desired air volume by the inverter control, the operation check of the overheat preventing means by the check means can be easily performed.

According to the fourth aspect of the present invention, the heating source of the heating means is steam (steam energy), and there is no risk of flammable solvent gas being ignited. Can be heated.
In the fifth aspect of the present invention, the steam supply is immediately stopped after the operation check of the overheat prevention means, and the air supplied from the drum inlet is not heated more than necessary, so that the temperature of the clothes is raised to the dry set temperature or higher. There is nothing. In addition, wasteful consumption of steam energy does not occur.

  In the invention described in claim 6, since both the inlet temperature detecting means and the overheat preventing means use the thermistor as the temperature detecting element, the temperature can be detected accurately. In particular, by configuring the overheat prevention means not by a thermostat but by a transistor circuit including a thermistor, when the drum inlet temperature reaches a predetermined overheat temperature, the overheat prevention means operates without taking time. It can be a high device.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a piping system diagram of a dry cleaner according to an embodiment of the present invention. The dry cleaner is divided into a main body 2 and a tank / filter kit 3.
A drum 4 for storing laundry is provided in the main body 2. The drum 4 is rotatably provided in the outer tub 5. The outer tub 5 is provided with an air inlet 6 for introducing air into the drum 4 and an air outlet 7 for discharging the air in the drum 4. The space between the air outlet 7 and the air inlet 6 is They are connected by a circulation path 8. The circulation path 8 is a closed path that connects the air outlet 7 and the air inlet 6.

  The dry cleaner is a device that performs dry cleaning using a dedicated solvent (for example, a petroleum solvent or a silicone solvent, and in this embodiment, a silicone solvent is used). Although dry cleaning has advantages such as less shrinkage of the laundry and easy removal of oil stains compared to washing the laundry with water, it is desirable that the solvent to be used should not be released into the environment as much as possible. Therefore, in this embodiment, all the solvent is recovered.

  That is, at the time of washing, a certain amount of solvent supplied from a tank 31 described later is stored in the outer tub 5 and washing is performed. After washing, the solvent is recovered from the outer tub 5 to the tank 31. Further, the drum 4 is rotated at a high speed, and the solvent is drained from the laundry. The removed solvent is also collected in the tank 31. Thereafter, the laundry is dried by circulating the air in the drum 4 through the circulation path 8 while the drum 4 is rotated at a low speed. The vaporized solvent that evaporates from the laundry by drying is also aggregated and recovered.

  In the drying step, the blower 10 is rotated by the blower motor 9, and the air in the drum 4 is circulated from the air outlet 7 through the circulation path 8 to the air inlet 6. The circulation path 8 is provided with drying coolers 11 and 12, and a drying heater 13 is provided in the vicinity of the air inlet 6. The air flowing from the drum 4 to the circulation path 8 through the air outlet 7 contains a vaporized solvent (solvent gas), and the air containing the solvent gas is cooled by the drying coolers 11 and 12, thereby The solvent gas inside liquefies. That is, the air containing the solvent passing through the circulation path 8 is cooled by the drying coolers 11 and 12 to condense the solvent and recover it from the air. Thereafter, air is heated by the drying heater 13, and heated air is supplied from the air inlet 6 into the drum 4. Within the drum 4, the heated air exchanges heat with the laundry to vaporize the solvent contained in the laundry. The evaporated solvent flows together with air from the air outlet 7 to the circulation path 8. By repeating this cycle, that is, a cycle in which the air in the drum 4 circulates in the circulation path 8, the laundry in the drum 4 is dried.

By the way, the solvent is flammable, and the vaporized solvent may ignite or explode unless the temperature control of the heated air is reliably performed in the drying process.
Therefore, in order to detect the temperature of the heated air supplied from the air inlet 6 to the drum 4, the inlet is provided on the downstream side of the drying heater 13 in the circulation path 8 (downstream side in the air flow direction, the same applies hereinafter). A drum inlet temperature thermistor 14 as temperature detecting means and an inlet temperature overheat preventing thermistor 15 included in the overheat preventing means are provided. Although not shown, the inlet temperature overheat prevention thermistor 15 is connected to a transistor circuit, for example, for detecting the temperature of 95 ° C. to disconnect the circuit through the transistor. The operating temperature is lower than that of the thermostat. There is an advantage that it can be detected more accurately and the temperature responsiveness is good.

  The circulation path 8 is provided with a drum outlet temperature thermistor 16 and a monitor outlet temperature overheat prevention thermistor 17 for determining whether or not the thermistor 16 has failed in order to detect the temperature of the air discharged from the air outlet 7. ing. Further, in order to detect the air temperature after being cooled by the downstream cooler of the two dry coolers 11 and 12, the circulation path 8 constitutes a part of the cooler temperature thermistor 18 and a safety circuit. A cooler temperature overheat prevention thermistor 19 is provided.

  Furthermore, in the circulation path 8 located between the drying cooler 12 and the drying heater 13, when the pressure in the circulation path 8 rises excessively, a breathing port 20 and a gate valve as a safety device for adjusting the pressure are provided. V14 is provided. Normally, the breathing port 20 is open, and the gate valve V14 is open so that air flows through the circulation path 8. In addition, an explosion-proof port 26 is provided to allow air containing solvent gas flowing through the circulation path 8 to ignite and cause an explosion when the air ignites. The explosion-proof port 26 is urged in a closing direction by a spring (not shown).

  The drying coolers 11 and 12 are connected to the refrigerator 23 via refrigerant passages 22a, 22b, and 22c. The refrigerator 23 is provided outside the main body 2. When the drying cooler solenoid valve 2Y inserted in the refrigerant passage 22a is opened, the refrigerant (for example, cold water) flows from the refrigerator 23 to the drying cooler 12 and the drying cooler 11 through the refrigerant passages 22a and 22b. 12 and the drying cooler 11 perform a cooling operation.

Steam passages 24 and 25 are connected to the drying heater 13. When the valve V20 inserted in the steam passage 24 is opened and the valve V12 inserted in the steam passage 25 is opened, steam (for example, steam at 110 to 120 ° C.) is supplied to the drying heater 13 and dried. The heater 13 performs a heating operation.
In the drying process, the rotation of the blower motor 9 and the opening and closing of the valves V20 and V12 are normally controlled based on the temperatures detected by the drum inlet temperature thermistor 14, the drum outlet temperature thermistor 16, and the cooler temperature thermistor 18. Further, in this embodiment, as will be described later, whether or not the inlet temperature overheat prevention thermistor 15 is normally operated is checked just before the drying process is completed, thereby confirming safety.

  The tank / filter kit 3 includes a tank 31 for storing a solvent, and a first filter 32 and a second filter 33 connected in series for filtering the solvent pumped out of the tank 31. One end of a pumping pipe 34 is connected to the lower surface of the tank 31. A valve V <b> 1 is inserted into the pumping pipe 34, and the other end is connected to the junction 35. The junction 35 is connected to the suction side of the solvent pump 36, and the discharge side of the solvent pump 36 is connected to the inlet of the three-way valve V6. One outlet of the three-way valve V6 is connected to one end of the flow pipe 37, and the other end of the flow pipe 37 is connected to the tank 31 via the valve V19. A middle portion of the flow pipe 37 (between the three-way valve V6 and the valve V19) is branched and connected to the series connection of the first filter 32 and the second filter 33. A flow pipe 38 is connected to the outlet side of the second filter 33, and the front end of the flow pipe 38 is connected to an inlet of a solvent heat exchanger 39 provided in the main body 2.

One end of the bypass pipe 40 is connected to the other outlet of the above-described three-way valve V6, and the other end is joined to the flow pipe 38 connected to the inlet of the solvent heat exchanger 39.
Therefore, by switching the outlet of the three-way valve V6, the solvent is supplied to the solvent heat exchanger 39 through the first filter 32 and the second filter 33, or bypassed by the bypass pipe 40 without passing through the filters 32 and 33, The heat exchanger 39 can be switched.

  A vapor pipe 41 and a refrigerant pipe 42 are disposed in the solvent heat exchanger 39. Each of the steam pipe 41 and the refrigerant pipe 42 is a pipe swirled in a coil shape, for example. Steam passages 43 and 44 are connected to the steam pipe 41. When the valve V21 inserted in the steam passage 43 is opened, the steam flows to the steam pipe 41 through the steam passage 43, and the steam is discharged through the steam passage 44. While the solvent passes through the solvent heat exchanger 39, heat exchange is performed between the high-temperature steam pipe 41 and the solvent, and the solvent is heated. On the other hand, refrigerant passages 45a and 45b are connected to the refrigerant pipe 42, and a refrigerant cooler electromagnetic valve 3Y is inserted into the refrigerant passage 45a. When the electromagnetic valve 3Y is opened, the refrigerant is passed through the refrigerant pipe. While the solvent passes through the solvent heat exchanger 39, heat exchange is performed between the solvent and the refrigerant pipe 42, and the solvent is cooled. By controlling the opening and closing of the valve V21 and the opening and closing of the solenoid valve 3Y for the solvent cooler, the solvent heat exchanger 39 switches between heating and cooling of the solvent, and the temperature of the solvent after passing through the solvent heat exchanger 39 Can be adjusted to a desired temperature.

One end of a circulation pipe 46 is connected to the outlet side of the solvent heat exchanger 39. The other end of the flow pipe 46 is connected to the inlet of the three-way valve V9. The flow pipe 46 is provided with a liquid temperature thermistor 47 for measuring the temperature of the solvent, and a liquid temperature overheat prevention thermistor 48 for preventing the liquid temperature from rising above a predetermined temperature. It has been.
The circulation pipe 46 is further provided with a soap concentration sensor 50 on the downstream side of the two thermistors.

One end of the liquid supply pipe 51 is connected to one outlet of the three-way valve V <b> 9, and the other end is connected to the outer tub 5 so that the solvent can be supplied into the drum 4. One end of a feedback pipe 52 is connected to the other outlet of the three-way valve V <b> 9, and the other end is connected to the tank 31.
In order to recover the solvent condensed by the drying coolers 11 and 12 in the circulation path 8, one end of a recovery pipe 62 is connected below the position where the drying coolers 11 and 12 in the circulation path 8 are arranged. The other end of the recovery pipe 62 is connected to the water separator 63. In the water separator 63, the water contained in the recovered solvent is separated, and the separated water is drained through the drain pipe 64. Then, the solvent is returned to the tank 31 through the recovery pipe 65.

A drainage port 55 is formed in the lowermost part of the outer tub 5, and a liquid level detection container 56 is connected to the drainage port 55. The liquid level detection container 56 is provided with two liquid level switches, a standard liquid level switch 57 and a drain liquid level switch 58. The liquid level detection container 56 also serves as a trap such as a button that has fallen off from the clothes falling from the drainage port 55 during washing.
One end of a recovery pipe 59 is connected to the lower end of the liquid level detection container 56. A valve V4 is inserted into the recovery pipe 59, and the other end of the recovery pipe 59 is connected to the junction 35.

Further, the other end of the soap pipe 61 whose one end is connected to the soap container 60 is joined to the joining point 35. A valve V17 is inserted into the soap pipe 61.
Next, the flow of the solvent in the piping system diagram shown in FIG. 1 will be described.
In the washing process, first, the solvent stored in the tank 31 is supplied to the drum 4 (outer tub 5). Therefore, the valve V1 is opened, the solvent pump 36 is driven, the three-way valve V6 is opened on the flow pipe 37 side, and the valve V19 is closed. As a result, the solvent in the tank 31 flows through the flow pipe 38 through the first filter 31 and the second filter 33, and after the temperature is adjusted by the solvent heat exchanger 39, the three-way valve V9 passes through the flow pipe 46. It flows to. The three-way valve V <b> 9 is open on the liquid supply pipe 51 side, and the solvent is supplied to the outer tank 5 through the liquid supply pipe 51. At the time of supply, the valve V4 is closed. The amount of the solvent accumulated in the outer tub 5 is detected by the liquid level switch 57. When a predetermined amount (a quantity suitable for washing) of the solvent is accumulated in the outer tub 5, the valve V9 is switched, and the liquid supply pipe 51 side is turned on. It is closed and the feedback tube 52 side is opened.

The solvent stored in the tank 31 is mixed with soap in advance, and the soap concentration in the solvent is measured by the soap concentration sensor 50 when the solvent passes through the flow pipe 46. When the soap concentration is low, the valve V17 is opened, and the soap in the soap container 60 is pumped out through the soap pipe 61 and mixed into the supplied solvent.
When supplying the solvent to the outer tub 5, the three-way valve V 6 is switched depending on the case, and the solvent is supplied to the solvent heat exchanger 39 through the bypass pipe 40 without passing through the filters 32 and 33 and supplied to the outer tub 5. You may make it do.

In the draining and draining process, the valve V4 is opened, the valve V1 is closed, and the solvent pump 36 is driven. The three-way valve V6 is opened on the flow pipe 37 side, the valve V19 is opened, and the solvent is returned to the tank 31.
Alternatively, the valve V19 is closed, and the solvent flowing through the flow pipe 37 passes through the filters 32 and 33, the flow pipe 39, the solvent heat exchanger 39, and the flow pipe 36, and flows through the feedback pipe 52 via the three-way valve V9. You may make it return to 31. In this way, the solvent after washing discharged from the outer tub 5 and the solvent drained from the laundry by centrifugal force can be purified and returned to the tank 31 by passing through the filters 32 and 33.

The feature of the dry cleaner according to this embodiment is that the quality of the overheat preventing means is determined every time the drying process is performed. This will be described below.
FIG. 2 is a block diagram showing a circuit configuration of a portion necessary for performing the above-described control.
The dry cleaner is provided with a control unit 70 composed of, for example, a microcomputer. The control unit 70 includes a timer 71 as a time measuring means configured by hardware or software. The temperature detected by the drum inlet temperature thermistor 14 is given to the controller 70. Further, when the overheat prevention circuit 15A is operated by detecting a predetermined temperature (for example, 95 ° C.) by the inlet temperature overheat prevention thermistor 15, a signal indicating the operation is given.

The control unit 70 controls the blower motor 9 to control the air volume by the blower 10. The blower motor 9 has an inverter circuit as a drive circuit, and the control unit 70 controls the rotation frequency of the blower motor 9 by controlling the frequency of the inverter.
The control unit 70 also controls opening and closing of the valve V20 and the valve V12.
FIG. 3 is a flowchart for explaining the operation of the control circuit shown in FIG. 2, that is, the check control of the overheat prevention means, which is a feature of this embodiment. This will be described in accordance with the flow of FIG.

The check control of the overheat prevention means is executed every time the drying process is performed. More specifically, it is performed during a certain time (for example, about 1 minute) until the end of the drying process, which is the final stage in the drying process.
When the check control starts, first, the frequency of the blower motor 9 is lowered from the normal control frequency, for example, 45 Hz, to about half, for example, 20 Hz. Thereby, the air volume by the blower 10 falls and air flows slowly in the circulation path 8. Simultaneously with the decrease in the frequency of the blower motor 9, the valve V20 and the valve V12 are opened, and the drying heater 13 starts a heating operation (step S1). In this embodiment, the valves V20 and V12 are simple open / close valves. However, if a valve whose opening degree can be controlled is used as the valves V20 and V12, the valves V20 and V12 are fully opened to perform a full heating operation. It is preferred to do so. Alternatively, when there are a plurality of heating steam paths, it is preferable to perform a full heating operation by fully opening the plurality of steam paths.

  Then, it is determined whether or not 1 minute has elapsed since the start of the check control (step S2). During less than 1 minute, the drum inlet temperature detected by the drum inlet temperature thermistor 14 becomes 105 ° C. or higher. (Step S3), and the inlet temperature overheat prevention thermistor 15 detects a predetermined overheat prevention temperature, for example, 95 ° C. to determine whether or not the overheat prevention circuit 15A is activated (Step S3). Step S4).

  The detected temperature of the drum inlet temperature thermistor 14 is lower than 105 ° C., and the overheat prevention circuit 15A is not activated (both NO in steps S3 and S4), and the drum inlet temperature thermistor 14 continuously detects 100 ° C. or higher for 10 seconds, for example. If it is (YES in step S5), the controller 70 stops the operation of the dry cleaner, assuming that the inlet temperature overheat prevention thermistor 15, the inlet temperature overheat prevention thermistor 15 or the overheat prevention circuit 15A is not normal.

  If it is determined in step S2 that the check control has started and one minute or more has elapsed, the drum inlet temperature thermistor 14 determines in step S3 that the drum inlet temperature is 105 ° C. or higher, or in step S4. If it is determined that the overheat prevention circuit is activated, the control proceeds to step S6. In step S6, the control frequency of the blower motor 9 is increased from, for example, 20 Hz to 45 Hz, which is the original control frequency, and the air volume of the blower 10 is returned to the original air volume. Thereby, the air circulation in the drum 4 and the circulation path 8 becomes smooth.

Then, it is determined whether or not the drum inlet temperature thermistor 14 has detected 100 ° C. or higher continuously for 10 seconds, for example (step S7). If the determination is affirmative, whether or not the overheat prevention circuit 15A has been activated. Is discriminated (step S8).
Even though the drum inlet temperature thermistor 14 continuously detects 100 ° C. or more for 10 seconds, the soot overheat prevention circuit 15A that operates when the inlet temperature overheat prevention thermistor 15 detects 95 ° C. is not activated. In such a case (NO in step S8), the controller 70 stops the operation of the dry cleaner on the assumption that the inlet temperature overheat prevention thermistor 15 or the overheat prevention circuit 15A has a trouble such as a failure.

On the other hand, when the determination at step S7 is negative or when the determinations at steps S7 and S8 are affirmed, the check control is terminated when the operation time count ends, for example, when one minute has elapsed from the start of the check control. At the same time, the drying process of the dry cleaner is completed.
In the above embodiment, the dry cleaner has been described as an example. However, the configuration of the present invention can also be applied to a dryer for dry cleaning in which the washing function is omitted from the dry cleaner.

It is a piping system diagram of the dry cleaner concerning one embodiment of this invention. It is a block diagram which shows the circuit structure of the dry cleaner of the part required in order to perform control used as the characteristics of this invention. It is a flowchart for demonstrating the check control used as the characteristic in this embodiment.

Explanation of symbols

4 Drum 5 Outer tank 6 Air inlet 7 Air outlet 8 Circulation path 9 Blower motor 10 Blower 11, 12 Drying cooler 13 Drying heater 14 Drum inlet temperature thermistor 15 Inlet temperature overheat prevention thermistor 15A Overheat prevention circuit V12, V20 Valve 70 Controller

Claims (6)

A drum having an air inlet and an outlet and for drying the laundry after being washed with a predetermined solvent;
A circulation path connected between the air outlet and the inlet of the drum;
Air blowing means for discharging air in the drum from the outlet and circulating it from the inlet to the drum through the circulation path;
Heating means for heating air sent from the inlet of the drum into the drum;
Solvent recovery means for liquefying and recovering the solvent by cooling the air containing the vaporized solvent that is provided in the circulation path and sent through the circulation path;
An inlet temperature detecting means provided at the inlet of the drum for detecting the temperature of the air entering the drum;
An overheat preventing means that is provided at the inlet of the drum and operates by detecting that the temperature of the air entering the drum has reached a predetermined overheat temperature;
The heating means, the air blowing means and the solvent recovery means are operated, heated air is sent into the drum, the solvent contained in the laundry is vaporized with the heated air, and the air containing the evaporated solvent is allowed to flow from the outlet to the circulation path. A drying process execution means for performing a drying process in which air is cooled in a circulation path to liquefy and recover the solvent;
In the drying step, by reducing the amount of air blown by the air blowing means and operating the heating means, the inlet temperature detecting means continuously detects a predetermined temperature or higher for a predetermined time, and the overheat preventing means is activated. Checking means for determining whether or not the overheat preventing means is good by determining whether or not to do;
Dry cleaner characterized by containing.   The dry cleaner according to claim 1, wherein the check unit performs the determination during a predetermined time until the end of the drying process. The blower means includes a blower fan provided in the circulation path, a motor for rotating the blower fan, and an inverter for frequency controlling the number of rotations of the motor,
The dry cleaner according to claim 2, wherein the check means lowers the frequency of the inverter to lower the rotational speed of the motor and lowers the blowing rate. The heating means has a heater pipe disposed at the inlet of the drum, a steam supply path for supplying steam to the heater pipe, and a valve for opening and closing the steam supply path,
The dry cleaner according to any one of claims 1 to 3, wherein the check means fully opens the valve of the steam supply path.   The dry cleaner according to claim 4, wherein the check unit closes the valve of the steam supply path immediately after determining that the overheat preventing unit is good. The inlet temperature detection means includes a thermistor,
The dry cleaner according to any one of claims 1 to 5, wherein the overheat prevention means includes a thermistor and a transistor circuit that operates in response to detection of a predetermined temperature by the thermistor.

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