JP6677848B1 - Drying equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently dry a purification element in a drying device. The present invention relates to a drying device. The drying device has a purifying element and a case accommodating the purifying element, and is installed with the purifying unit having the first and second openings formed in the case removed from the diesel machine, and from the first opening to the inside of the case. The purification element is dried by the hot air sent to. Further, the drying device has a suction mechanism that sucks hot air inside the case, and a control unit that switches between a hot air feeding state and a hot air stop state. The control unit includes a suction pipe that connects the mechanism main body and a temperature sensor that is arranged in the downstream region of the suction path of the suction mechanism that is on the downstream side of the blower. When it becomes, the hot air supply state is switched to the hot air stop state. [Selection diagram] FIG.

Description

  The present invention relates to a drying device for drying a purification element including a purification element that purifies exhaust gas from a diesel engine, with the purification unit removed from the diesel machine.

Automobile, train, ship, a generator, the exhaust gas from a diesel engine mounted on the machine, such as a pump, include particulate matter (PM, Particulate Matter), nitrogen oxides (NO _X) and the like. Therefore, in a machine equipped with a diesel engine, that is, in a diesel machine, a DPF (Diesel Particulate Filter) for trapping particulate matter and a urea SCR (Diesel Particulate Filter) for reducing nitrogen oxides. A purifying unit including purifying elements such as Selective Catalytic Reduction (Selective Catalytic Reduction) is installed.

  In such a diesel machine, particulate matter and ash, which is combustion residue of engine oil, are deposited on the DPF. Also, urea-derived solids such as cyanuric acid are deposited on the urea SCR. Therefore, in order to remove the deposited material deposited on the purifying element, it is possible to clean the purifying element or the purifying unit using a cleaning liquid with the purifying element or the purifying element unit including the purifying element removed from the diesel machine. Is being done. After the cleaning, the purifying element is wet so as to contain moisture, and thus the purifying element is dried by an electric furnace or a hot air blower. (For example, see Patent Document 1)

JP 2006-205044 A

  However, electric furnaces only evaporate the water in the purification element by the heat of the electric furnace to dry the purification element. Therefore, a lot of time is spent to sufficiently dry the purification element by the electric furnace. Further, when the purification element is dried by the electric furnace and the hot air blower, the purification element is heated above its heat-resistant temperature, and as a result, the purification element may be damaged. That is, in the drying using an electric furnace or a hot air blower, the purification element cannot be efficiently dried.

  In view of such a situation, it is desired to provide a drying device that can efficiently dry the purifying element.

In order to solve the above-described problem, a drying device according to one aspect includes a purifying element for purifying exhaust gas from a diesel engine and a case containing the purifying element, and the exhaust gas is provided inside the case. First and second openings for passing through the case are formed in the case, and the purification unit is installed in a state detached from the diesel machine, and the purification element is dried by hot air supplied from the first opening to the inside of the case. a constructed drying apparatus so as to suction and Kyusuru heater feeding hot air to the inside of the casing, configured to allow the suction of the hot air is fed to the inside of the casing from the heater a mechanism, the heater is fed to the hot Kyusuru hot air feeding state and the heater is to be performed a hot air control to switch the hot stop state for stopping the feeding of the hot air And a configured control unit to the heater has a blower opening for feeding the hot air, the cleaning unit is installed the first opening so as to face the blower opening of said heater, said suction mechanism However, the suction mechanism main body having a blower configured to be capable of sucking the hot air, and the hot air fed into the case can be fed from the second opening of the purification unit to the suction mechanism main body. The second opening and the suction mechanism main body are connected to each other, and includes a flexible suction pipe, and a temperature sensor configured to measure the temperature of the hot air, wherein the suction mechanism main body includes a housing and , which is connected to the proximal end of the suction pipe, and having an intake port disposed in said housing, and said suction mechanism body fed evacuation can configured outlet the hot air, the The tip of the suction tube is in the second opening Disconnect capable connected, said hot air being adapted to flow through the suction path extending to the exhaust port from the suction pipe through the suction mechanism body, said temperature sensor, the flow of the hot air than the blower The control unit and the blower are arranged in a housing of the suction mechanism, and the heater is detachable with respect to the control unit and the suction mechanism main body. And the control unit is configured to switch from the hot air supply state to the hot air stop state when a measured value of the temperature measured by the temperature sensor is equal to or greater than a hot air stop threshold.

  In the drying device according to one aspect, the purification element can be efficiently dried.

FIG. 1 is a perspective view schematically showing a drying apparatus according to an embodiment with a DPF unit installed therein. FIG. 2 is a block diagram of a drying device according to one embodiment. FIG. 3 is a front view schematically showing the suction mechanism of the drying apparatus according to the embodiment with its front door removed. FIG. 4 is a right side view schematically showing the suction mechanism of the drying apparatus according to the embodiment with its right side panel removed. FIG. 5 is a sectional view taken along line AA of FIG. FIG. 6 is a flowchart for explaining a method of drying the DPF using the drying device according to one embodiment.

  A drying device according to one embodiment will be described below. In the present embodiment, a case will be described in which the drying device dries a DPF unit used for a diesel vehicle, for example, a truck, a tractor, a bus, or the like on which a diesel engine is mounted. However, the drying device can also dry a DPF unit used for a diesel machine such as a railway, a ship, a generator, a pump, or the like, on which a diesel engine is mounted.

  Further, the drying device can also dry an exhaust gas purification unit including an exhaust gas purification element other than the DPF. For example, the drying device can dry a urea SCR unit including the urea SCR. The drying device can also dry a catalyst unit including a catalyst such as an oxidation catalyst and a three-way catalyst. Furthermore, the drying device can also dry the exhaust gas purification unit configured by connecting the urea SCR unit and the DPF unit in the direction in which the exhaust gas flows.

"Outline of drying equipment"
The outline of the drying device according to the present embodiment will be described with reference to FIGS. As shown in FIG. 1, the drying device is configured such that the DPF unit 1 removed from the diesel vehicle can be installed. The DPF unit 1 includes a ceramic DPF 2 (shown by a broken line) and a case 3 that accommodates the DPF 2. Then, the drying device dries the DPF unit 1, particularly, the DPF 2. However, the DPF to be dried may be made of a material other than ceramic, for example, the DPF may be made of stainless steel. When the exhaust gas purification unit is configured by connecting the urea SCR unit and the DPF unit in the direction in which the exhaust gas flows as described above, the case also connects the case of the urea SCR unit and the DPF unit. Should be considered as being composed by

  The case 3 has a first opening 4 and a second opening 5 for passing the exhaust gas through the case 3. The DPF unit 1 has been removed from the diesel vehicle. In particular, the DPF unit 1 may be a part of a muffler of a diesel vehicle that passes exhaust gas from a diesel engine.

  As shown in FIGS. 1 to 5, the drying device is configured such that hot air (arrow H) supplied from the first opening 4 to the inside of the case 3 with the DPF unit 1 removed from the diesel vehicle installed in the drying device. ) To dry the DPF 2. Such a drying device has a suction mechanism 10 configured to be able to suction the hot air fed into the case 3 of the DPF unit 1.

  As shown in FIGS. 1 to 4, the drying device is also configured to be capable of performing hot air control for switching between a hot air supply state for supplying hot air and a hot air stop state for stopping supply of hot air. 1 (shown by broken lines in FIGS. 1, 3 and 4). The control unit 20 includes electronic components such as a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, an input interface, an output interface, and an electric circuit in which the electronic components are arranged. It is good to include.

  As shown in FIGS. 2 to 5, the suction mechanism 10 includes a suction mechanism main body 11 having a blower 12 configured to be capable of sucking hot air. The suction mechanism 10 has a suction pipe 13 that connects the second opening 5 of the DPF unit 1 and the suction mechanism main body 11. The suction pipe 13 is configured so that the hot air fed into the case 3 can be sent from the second opening 5 to the suction mechanism main body 11. The suction mechanism main body 11 has an exhaust port 14 configured to discharge the hot air fed to the suction mechanism main body 11. The suction mechanism 10 has a temperature sensor 15 configured to measure the temperature of hot air.

In such a drying apparatus, the hot air flows through a suction path P extending from the suction pipe 13 to the exhaust port 14 through the suction mechanism main body 11. The temperature sensor 15 is arranged in a downstream area P1 of the suction path P located closer to the downstream of the flow of the hot air than the blower 12 is. The control unit 20 is configured to switch from the hot air supply state to the hot air stop state when the measured value T of the temperature measured by the temperature sensor is equal to or more than the hot air stop threshold T1.

  Furthermore, the outline of the drying device can be configured as follows. As shown in FIGS. 4 and 5, a temperature sensor 15 is disposed at the exhaust port 14 of the suction mechanism 10. As an example, when the DPF unit 1 having the DPF 2 is installed in the drying device, the hot air stop threshold T1 can be set to about 120 ° C. However, the hot air stop threshold may be other than about 120 ° C.

  The control unit 20 is configured to maintain the hot air stop state after the measured value T of the temperature measured by the temperature sensor 15 is equal to or more than the hot air stop threshold value T1 and switches from the hot air supply state to the hot air stop state. I have. Further, the control unit 20 is configured to be able to execute suction control for switching between a suction operation state in which the suction mechanism 10 suctions hot air and a suction stop state in which the suction mechanism 10 stops suctioning hot air. The control unit 20 switches the temperature measurement value T to the hot air stop threshold T1 or more, switches from the hot air supply state to the hot air stop state, and maintains the hot air stop state. In such a case, the state is switched from the suction operation state to the suction stop state.

  The suction stop threshold T2 is smaller than the hot air stop threshold T1. As an example, the suction stop threshold T2 can be set to about 50C. In particular, when the DPF unit 1 having the DPF 2 is installed in the drying device, the suction stop threshold T2 can be set to about 50C. However, the suction stop threshold may be a value other than about 50 ° C.

"Details of DPF unit"
Here, referring to FIG. 1, the details of the DPF unit can be configured as follows. The case 3 of the DPF unit 1 has a cylindrical body 3a. The body 3a extends linearly. In the purification unit of the present invention, the body may be formed to be curved. For example, the body may be formed in a substantially U shape, a substantially S shape, or the like.

  The first and second openings 4 and 5 open toward opposite sides. However, in the purification unit of the present invention, the first and second openings may open in all directions with respect to each other. For example, the first and second openings may open in substantially the same direction with respect to each other.

"Details of drying equipment"
With reference to FIGS. 1 to 5, the details of the drying apparatus according to the present embodiment can be configured as follows. As shown in FIGS. 1 and 2, the drying device includes a heater 30 configured to supply hot air. The heater 30 has an air outlet 31 for sending out hot air. The heater 30 is electrically connected to the control unit 20. The heater 30 is detachably connected to the control unit 20. Therefore, the hot air control of the control unit 20 switches between a hot air supply state in which the heater 30 supplies hot air and a hot air stop state in which the heater 30 stops supplying hot air.
For example, the heater 30 can be a hot air jet heater. However, the heater is not limited to a hot-air jet heater.

  As shown in FIG. 1, the drying apparatus has a gantry 40 on which the DPF unit 1 can be mounted. The gantry 40 is configured such that, with the DPF unit 1 placed on the gantry 40, the first opening 4 of the case 3 of the DPF unit 1 faces the air outlet 31 of the heater 30 in the horizontal direction.

  As shown in FIGS. 3 and 5, the suction mechanism main body 11 has an air inlet 16 connected to the suction pipe 13. As shown in FIGS. 1 and 2 to 4, the suction mechanism main body 11 further has a housing 17. The control unit 20 is disposed in the upper portion 17a of the housing 17. That is, the control unit 20 is provided in the suction mechanism 10. In this case, the heater 30 is detachably connected to the suction mechanism main body 11 and the control unit 20.

  The blower 12 is arranged in the lower part 17b of the housing 17. Referring to FIG. 1 and FIGS. 3 to 5, a front door 17 c that opens and closes the lower portion 17 b of the housing 17 is provided at the front of the lower portion 17 b of the housing 17 and the lower portion 17 b of the housing 17. A back panel 17d, a left side panel 17e, and a right side panel 17f are provided on the back, left side, and right side of the device. Three or more casters 18 are attached to the bottom surface of the housing 17. Each caster 18 has wheels 18a

  As shown in FIGS. 3 and 4, the blower 12 is electrically connected to the control unit 20. Referring to FIGS. 3 to 5, the blower 12 has a fan portion 12 a having a plurality of runners (not shown) arranged in a cylindrical shape.

As shown in FIG. 1, the distal end 13 a of the suction tube 13 is detachably connected to the second opening 5 of the case 3 of the DPF unit 1. A proximal end portion 13 b of the suction pipe 13 is connected to an intake port 16 of the suction mechanism main body 11. The suction tube 13 has flexibility. In a plan view, the suction pipe 13 extends substantially linearly between the second opening 5 of the case 3 of the DPF unit 1 and the suction port 16 of the suction mechanism main body 11. In a plan view, the air outlet 31 of the heater 30, the first and second openings 4 and 5 of the case 3 of the DPF unit 1, and the suction pipe 13 are arranged substantially in a straight line.

Further, regardless of the direction viewed from any direction, it is preferable that the suction pipe 13 extends substantially linearly between the second opening 5 of the case 3 of the DPF unit 1 and the suction port 16 of the suction mechanism main body 11. In any case, the air outlet 31 of the heater 30, the first and second openings 4 and 5 of the case 3 of the DPF unit 1, and the suction pipe 13 substantially extend along a straight line. Preferably, they are arranged. However, the suction tube may extend while bending vertically.

  As shown in FIGS. 4 and 5, the exhaust port 14 is arranged on the outer peripheral side of the fan portion 12a. The exhaust port 14 opens in a direction substantially orthogonal to a direction along the central axis 12b of the fan section 12a. The exhaust port 14 is arranged on a rear panel 17 d of the housing 17. The exhaust port 14 is substantially directly connected to the blower 12. The temperature sensor 15 disposed in such an exhaust port 14 is electrically connected to the control unit 20.

As shown in FIGS. 3 and 5, the intake port 16 is disposed on the center axis 12 b of the fan section 12 a of the blower 12. Further, the intake port 16 opens in a direction along the central axis 12b of the fan section 12a. The intake port 16 is disposed on a left side panel 17e of the housing 17. The intake port 16 is located above the exhaust port 14. Inlet 16 is substantially directly connected to blower 12.

Referring to FIG. 1 and FIGS. 3 to 5, the suction path P includes, in addition to the downstream area P <b> 1, an intermediate area P <b> 2 from the intake port 16 to the blower 12 and an upstream area P <b> 3 which is the suction pipe 13. In a plan view, the downstream area P1 is disposed so as to be substantially orthogonal to the intermediate area P2. In plan view, the intermediate region P2 and the upstream region P2 are arranged substantially along a straight line. It is preferable that the intermediate region P2 and the upstream region P2 are arranged substantially along a straight line, regardless of the direction from which they are viewed.

  In the suction path P, when a plurality of runners in the fan section 12a of the blower 12 rotate, hot air is sucked from the suction pipe 13 toward the blower 12 by the rotation of the plurality of runners. Thereafter, the hot air is discharged from the fan portion 12a of the blower 12 to the exhaust port 14 toward the outer periphery from the central axis 12b of the blower 12.

"Details of control unit settings"
Details of the setting of the control unit 20 will be described. In the drying device according to the present embodiment, when the temperature measurement value T measured by the temperature sensor 15 is about 120 ° C. in a state where the temperature sensor 15 is disposed at the exhaust port 14, the case 3 of the DPF unit 1 Tend to be about 250 ° C. Furthermore, the heat resistance temperature of DPF2, especially DPF2 made of ceramic is about 250 ° C. In view of these, as described above, the hot air stop threshold T1 is set to about 120 ° C. Further, when the measured value T of the temperature measured by the temperature sensor 15 becomes equal to or more than the hot air stop threshold T1, the control unit 20 Is configured to switch the heater 30 from the hot air supply state to the hot air stop state. However, the hot air stop threshold is not limited to this. The hot air stop threshold can be changed in consideration of the installation position of the temperature sensor, the heat-resistant temperature of the purification element, temperature variation, and the like.

  Further, in the drying device according to the present embodiment, when the temperature measurement value T measured by the temperature sensor 15 is about 50 ° C. or less in a state where the temperature sensor 15 is disposed at the exhaust port 14, the DPF unit 1 The inside of case 3 tends to be in a state in which the moisture of DPF 2 cannot be sufficiently removed. This condition can also occur in purification units other than the DPF. In view of these, as described above, the suction stop threshold T2 is set to about 50 ° C., and when the measured value T of the temperature measured by the temperature sensor 15 becomes equal to or less than the suction stop threshold T2, the control unit 20 Is configured to switch the suction mechanism 10 from the suction operation state to the suction stop state. However, the suction stop threshold is not limited to this. The suction stop threshold value can be changed in consideration of the installation position of the temperature sensor, the structure of the case of the purification unit, the state in the case, temperature variation, and the like.

"Drying method"
A method of drying the DPF 2 using the drying device according to the present embodiment will be described with reference to FIG. First, the DPF unit 1 is removed from the diesel vehicle (step S1). In the drying device, the heater 30 is in the hot air stop state, and the suction mechanism 10 is in the suction stop state. That is, the drying device is in the stop mode. (Step S2) The DPF unit 1 is set in a drying device (Step S3). The user switches the heater 30 from the hot air stop state to the hot air supply state and switches the suction mechanism 10 from the suction stop state to the suction operation state in order to instruct the start of drying. That is, the user sets the drying device to the heating mode (step S4). With the hot air being sent from the heater 30 to the suction mechanism 10 through the DPF unit 1, the DPF 2 is dried by feeding and suctioning the hot air.

  The control unit 20 determines whether or not the measured value T of the temperature measured by the temperature sensor 15 is equal to or more than the hot air stop threshold T1 (Step S5). When the measured value T of the temperature is less than the hot air stop threshold value T1 (NO), the control unit 20 maintains the heater 30 in the hot air supply state and maintains the suction mechanism 10 in the suction operating state. That is, the control unit 20 maintains the drying device in the heating mode. (Step S4). When the measured value T of the temperature is equal to or more than the hot air stop threshold value T1 (YES), the control unit 20 switches the heater 30 from the hot air supply state to the hot air stop state, and thereafter maintains the suction mechanism 10 in the suction operation state. That is, the control unit 20 sets the drying device to the blowing mode (step S6). In this blowing mode, the DPF 2 can be dried by suction of the hot air while the hot air is sucked from the DPF unit 1 to the suction mechanism 10.

  The control unit 20 determines whether or not the measured value T of the temperature measured by the temperature sensor 15 is equal to or less than the suction stop threshold T2 (Step S7). When the measured value T of the temperature is larger than the suction stop threshold value T2 (NO), the control unit 20 maintains the heater 30 in the hot air stop state and maintains the suction mechanism 10 in the suction operation state. That is, the control unit 20 maintains the drying device in the blowing mode. (Step S6). When the measured value T of the temperature is equal to or smaller than the suction stop threshold value T2 (YES), the control unit 20 maintains the heater 30 in the hot air stop state and switches the suction mechanism 10 from the suction operation state to the suction stop state. That is, the control unit 20 sets the drying device to the stop mode (step S8). The drying of the DPF 2 is completed (Step S9).

  As described above, in the drying device according to the present embodiment, the suction mechanism 10 causes the hot air to flow through the second opening 5 so that the hot air can efficiently flow from the first opening 4 to the second opening 5 through the inside of the case 3 of the DPF unit 1. Aspirate through opening 5. By the efficient flow of the hot air based on the suction mechanism 10, the DPF 2 inside the case 3 can be efficiently dried.

  Further, the temperature sensor 15 is disposed in the downstream area P1 of the suction path P, and the hot air passing through the downstream area P1 of the suction path P is hardly affected by the suction force generated by the blower 12 of the suction mechanism main body 11. Therefore, based on the temperature accurately measured by the temperature sensor 15, the drying device can be controlled so that the DPF 2 is efficiently dried.

  Even if the temperature sensor 15 arranged in the downstream area P1 of the suction path P comes off, the temperature sensor 15 moves toward the exhaust port 14 away from the blower 12 by the flow of hot air. Therefore, the temperature sensor 15 does not contact the blower 12. As a result, it is possible to prevent the temperature sensor 15 and the blower 12 from being damaged by mutual contact.

  Based on the correlation between the temperature of the hot air passing through the downstream area P1 of the suction path P and the temperature of the hot air passing inside the DPF unit 1, the hot air stop threshold T1 can be set in accordance with the heat-resistant temperature of the DPF unit 1. . Therefore, the supply of hot air to the DPF unit 1 can be reliably stopped before the DPF 2 is deteriorated due to the temperature of the hot air passing through the inside of the DPF unit 1 exceeding the heat-resistant temperature of the DPF unit 1. On the other hand, the supply of hot air to the DPF unit 1 can be continued until immediately before the temperature of the hot air passing through the inside of the DPF unit 1 exceeds the heat-resistant temperature of the DPF unit 1, so that the DPF 2 can be sufficiently dried. Therefore, the DPF 2 inside the DPF unit 1 can be efficiently dried by such efficient control of the hot air.

  In the drying device according to the present embodiment, the temperature sensor 15 is disposed at the exhaust port 14, and the hot air passing through the exhaust port 14 is hardly affected by the suction force provided by the blower 12 of the suction mechanism main body 11. Therefore, based on the temperature accurately measured by the temperature sensor 15, the drying device can be controlled so that the DPF 2 is efficiently dried.

  In the drying apparatus according to the present embodiment, the hot air stop threshold T1 is set to about 120 ° C. in a state where the DPF unit 1 having the DPF 2 is installed. The hot air stop threshold T1 corresponds to the temperature of the hot air passing through the exhaust port 14 when the temperature of the hot air passing through the DPF unit 1 is about 250 ° C., and the heat-resistant temperature of the DPF 2 is about 250 ° C. Therefore, by setting the hot air stop threshold value T1, it is possible to efficiently prevent the temperature of the hot air passing through the DPF unit 1 from exceeding the heat resistant temperature of the DPF 2.

  In the drying device according to the present embodiment, the control unit 20 maintains the hot air stop state after the measured value T of the temperature becomes the hot air stop threshold value T1 or more and switches from the hot air supply state to the hot air stop state. It is configured. Therefore, the supply of hot air to the DPF unit 1 can be reliably stopped before the DPF 2 is deteriorated due to the temperature of the hot air passing through the inside of the DPF unit 1 exceeding the heat-resistant temperature of the DPF unit 1. On the other hand, the supply of hot air to the DPF unit 1 can be continued until immediately before the temperature of the hot air passing through the inside of the DPF unit 1 exceeds the heat-resistant temperature of the DPF unit 1, so that the DPF 2 can be sufficiently dried. Therefore, the DPF 2 inside the DPF unit 1 can be efficiently dried by such efficient control of the hot air.

  In the drying device according to the present embodiment, the control unit 20 can execute suction control for switching between a suction operation state in which the suction mechanism 10 suctions hot air and a suction stop state in which the suction mechanism 10 stops suctioning hot air. The control unit 20 measures the temperature while maintaining the hot air stopped state after the measured value T of the temperature is equal to or more than the hot air stop threshold value T1 and switching from the hot air supply state to the hot air stopped state. When the value T becomes equal to or less than the suction stop threshold T2, the suction operation state is switched to the suction stop state, and the suction stop threshold T2 is smaller than the hot air stop threshold T1. In particular, the suction stop threshold T2 can be set to about 50 ° C. In such a drying apparatus, even after the supply of the hot air is stopped, the suction mechanism 10 can cause the flow of air in the DPF unit 1 until the temperature of the DPF 2 drops sufficiently away from the heat-resistant temperature. it can. Therefore, it is possible to reliably prevent the temperature of the DPF 2 from exceeding the heat-resistant temperature due to the flow of air based on the suction mechanism 10.

  Although the embodiments of the present invention have been described so far, the present invention is not limited to the above-described embodiments, and the present invention can be modified and changed based on the technical idea.

DESCRIPTION OF SYMBOLS 1 ... DPF unit (purification unit), 2 ... DPF (purification element), 3 ... Case, 4 ... 1st opening, 5 ... 2nd opening 10 ... Suction mechanism, 11 ... Suction mechanism main body, 12 ... Blower, 13 ... Suction Pipe, 14: exhaust port, 15: temperature sensor, 16: intake port, 17: housing, 20: control unit, 30: heater, 31: blow port, P: suction path, P1: downstream area H: hot air T ... Temperature measured value, T1: hot air stop threshold, T2: suction stop threshold

Claims (6)

Purification having a purifying element for purifying exhaust gas from a diesel engine and a case accommodating the purifying element, and having first and second openings formed in the case for passing the exhaust gas into the case. A drying device configured to install the unit detached from a diesel machine, and to dry the purification element by hot air supplied to the inside of the case from the first opening,
A heater for supplying hot air to the inside of the case,
When configured suction mechanism so as to allow suction the hot air is fed to the inside of the casing from the heater,
A control unit configured to be able to execute hot air control for switching a hot air supply state in which the heater supplies the hot air and a hot air stop state in which the heater stops supplying the hot air,
The heater has an air outlet for sending out the hot air,
The purification unit is installed so that the first opening is opposed to an air outlet of the heater,
The suction mechanism,
A suction mechanism main body having a blower configured to be capable of sucking the hot air,
A flexible suction pipe that connects the second opening and the suction mechanism main body so that the hot air supplied to the inside of the case can be supplied from the second opening of the purification unit to the suction mechanism main body. When,
A temperature sensor configured to be able to measure the temperature of the hot air,
The suction mechanism body, a housing, which is connected to the proximal end of the suction pipe, and wherein the air inlet is disposed in the housing, is drainable configure the hot air that is fed to the suction mechanism body and a that the exhaust port,
A distal end of the suction tube is detachably connected to the second opening,
The hot air flows through a suction path extending from the suction pipe through the suction mechanism body to the exhaust port,
The temperature sensor is disposed in a downstream region of the suction path located closer to the downstream of the flow of the hot air than the blower,
The control unit and the blower are arranged in a housing of the suction mechanism,
The heater is detachably connected to the control unit and the suction mechanism main body,
The drying device, wherein the control unit is configured to switch from the hot air supply state to the hot air stop state when a measured value of the temperature measured by the temperature sensor is equal to or more than a hot air stop threshold.   The drying device according to claim 1, wherein the temperature sensor is disposed at the exhaust port.   The drying device according to claim 2, wherein the hot air stop threshold is set to 120C when the purification unit is a DPF unit and the purification element is a DPF.   The control unit is configured to maintain the hot air stop state after the measured value of the temperature measured by the temperature sensor is equal to or more than the hot air stop threshold, and after switching from the hot air supply state to the hot air stop state. The drying device according to claim 1, wherein The control unit is configured to be capable of executing a suction control in which the suction mechanism switches between a suction operation state in which the hot air is suctioned and the suction mechanism in which the suction mechanism stops suctioning the hot air.
The control unit is a state in which the measured value of the temperature measured by the temperature sensor is equal to or greater than the hot air stop threshold, and after switching from the hot air supply state to the hot air stop state, the hot air stop state is maintained. When the measured value of the temperature is equal to or less than the suction stop threshold, it is configured to switch from the suction operation state to the suction stop state,
The drying device according to claim 4, wherein the suction stop threshold is smaller than the hot air stop threshold.   The drying device according to claim 5, wherein the suction stop threshold is set to 50C.