KR101305879B1 - Steam Thawing Apparatus and Driving Control Method Thereof - Google Patents

Abstract

The present invention relates to a steam thawing machine and a drive control method thereof.
According to the present invention, in the case of cold start, the heater is heated and the pump is intermittently operated for a set time to draw water from the water supply at a low speed, and then the heater continuously operates the pump at the same time as the heater reaches the steam generation temperature. By supplying water to the steam generator, by supplying water to the steam generator at the same time as the completion of heating of the heater to generate steam immediately, compared to the prior art that begins to supply water after the heating of the heater at the cold start, Steam generation time can be shortened.

Description

Steam Thawing Apparatus and Driving Control Method Thereof}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam thawing machine and, more particularly, to a steam thawing machine and a drive control method thereof for generating steam at high speed during cold start.

In general, the steam thawing machine is used to remove the freezing of the water pipe in the winter or to clean the contaminants of various machinery by providing a high temperature steam generated by heating the water.

Republic of Korea Patent Publication No. 10-1060684 has been proposed a steam thawing machine for generating steam by supplying water to the steam generator after heating the heater provided in the steam generator to a predetermined temperature.

Since the steam thawing machine heats the heater to a predetermined temperature and then supplies water to the steam generator to generate water by heating the water by the heater, it takes time to supply water to the steam generator after the heater is heated. There is a problem that the time is delayed.

In addition, the above-described conventional steam thawing machine does not provide the state information of the heater to the user, there is a problem that there is a risk of causing a safety accident in use because it can not determine the overheat state of the heater.

Republic of Korea Patent Publication No. 10-1060684

The present invention has been proposed to solve the problems of the prior art as described above, the object of which is to complete the heating of the heater of the steam generator to the steam generation temperature at the time of cold start and at the same time supply steam to the steam generator It is intended to occur at a high speed.

Another object of the present invention is to provide a user with state information of a heater to prevent a safety accident during use.

In the steam thawing apparatus according to the first embodiment of the present invention for achieving the above object, a steam generator having a steam generator for receiving the water is heated by a heater to generate the steam for thawing, A sensor for detecting a temperature and applying the temperature to a controller; A pump for pumping water supplied to the steam generator under control of the controller; A switching unit for switching the power supply to the heater according to the control of the controller; At start-up, the switching unit supplies power to the heater to heat the heater to intermittently operate the pump to draw water from the water supply at a low speed for a predetermined time, and then continuously operate the pump to operate the steam at a temperature capable of generating steam. At the same time it comprises the control unit for controlling to supply water to the steam generator.

According to the steam thawing apparatus according to the first embodiment of the present invention, the control unit includes an input unit for inputting various driving commands and information to the microprocessor by manual operation; A display unit for displaying a driving state of the steam thaw under the control of the microprocessor; A memory for storing a program for control, storing general data necessary for control, and providing the program and data to a microprocessor; A matching unit for matching the sensor, the switching unit and the pump to a microprocessor; The control unit outputs a control signal to the switching unit through the matching unit according to the driving instruction through the input unit and supplies power to the heater by the switching unit to output the control signal to the pump through the matching unit while heating the heater, thereby intermittently operating the pump. It includes a microprocessor for drawing water from the supply source at a low speed for a predetermined time, and then outputs a control signal to the pump through the matching unit to continuously operate the pump.

Further, according to the steam thawing apparatus according to the first embodiment of the present invention, the microprocessor switches the power supply to the heater by the switching unit so that the temperature of the heater can maintain the set temperature without exceeding the allowable limit temperature. The pump may be driven for a predetermined time when the driving stop command is input through the input unit to discharge residual water inside the pump and the steam generator.

In addition, according to the steam thawing apparatus according to the first embodiment of the present invention, the microprocessor controls the switching unit to heat the heater in response to the steam temperature set through the input unit.

According to the steam thawing apparatus according to the first embodiment of the present invention, the microprocessor controls the amount of power supplied to the heater by controlling the switching time of the switching unit in response to the temperature set through the input unit.

On the other hand, the steam thawing apparatus according to the second embodiment of the present invention for achieving the above object, in the steam thawing apparatus having a steam generator for receiving the water is heated by the heater to generate the steam for thawing, A sensor for detecting a temperature and applying the temperature to a controller; A pump for pumping water supplied to the steam generator under control of the controller; A heater power supply unit controlling an amount of power supplied to the heater by controlling a pulse width or frequency of a pulse waveform current applied to the heater according to the control of the controller; At start-up, the heater is supplied with power to the heater to heat the heater, and the pump is intermittently operated to draw water from the water supply at a low speed for a predetermined time, and then the pump is continuously operated to allow the heater to generate steam. It comprises the control unit for controlling to supply water to the steam generator at the same time reaches.

According to the steam thawing apparatus according to the second embodiment of the present invention, the control unit controls the heater power supply unit to adjust the amount of power supplied to the heater in response to a set temperature.

In addition, according to the steam thawing apparatus according to the second embodiment of the present invention, the control unit includes an input unit for inputting various driving commands and information to the microprocessor by manual operation; A display unit for displaying a driving state of the steam thaw under the control of the microprocessor; A memory for storing a program for control, storing general data necessary for control, and providing the program and data to a microprocessor; A matching unit for matching the sensor, the heater power supply and the pump to a microprocessor; The control signal is output to the heater power supply unit through the matching unit according to the driving instruction through the input unit to supply power to the heater by the heater power supply unit to heat the heater, and output the control signal to the pump through the matching unit to intermittently operate the pump. It comprises a microprocessor for drawing water from the water supply at a low speed for a predetermined time, and then outputs a control signal to the pump through the matching unit to continuously operate the pump.

According to a steam thawing apparatus according to a second embodiment of the present invention, the heater power supply unit includes: an input unit for converting a voltage of a commercial AC power input; A rectifier for rectifying AC power applied from the input part and converting the AC power into DC power; A pulse generator for generating a pulse by receiving DC power from the rectifier and outputting a current of a pulse waveform, and adjusting an amount of power output by adjusting a pulse width or frequency of a pulse waveform current according to a control signal; And an output unit converting the pulse waveform current output from the pulse generator into a voltage usable by the heater and outputting the converted voltage to the heater.

On the other hand, the drive control method of the steam thawing apparatus according to the present invention for achieving the object as described above, the step of heating the heater by supplying power to the heater when the control unit receives a drive start command; Outputting a control signal to the pump to control the pump for a predetermined time to drive the pump to draw water from the water supply at a low speed for a predetermined time; The control unit includes a step of continuously operating the pump to supply water to the steam generator to generate and output steam by the steam generator.

According to the driving control method of the steam thawing apparatus according to the present invention, if the control unit receives a driving stop command during steam generation, the step of driving the pump for a predetermined time to discharge the residual water in the pump and the steam generator further comprises the step of ending the operation; Characterized in that.

In addition, according to the driving control method of the steam thawing apparatus according to the present invention, the control unit detects the temperature of the heater during steam generation; The control unit further comprises the step of preventing the overheating of the heater by blocking the power supply to the heater when the temperature of the heater exceeds the set temperature.

In addition, according to the driving control method of the steam thaw according to the present invention, the step of setting the input steam temperature by the controller; And controlling the power supply to the heater to heat the heater to correspond to the steam temperature.

In addition, according to the driving control method of the steam thaw according to the present invention, the control unit further comprises the step of controlling the power supply to the heater so that the temperature of the heater does not exceed the allowable limit temperature to maintain the set temperature. do.

Further, according to the driving control method of the steam thawing apparatus according to the present invention, the control unit controls the amount of power supplied to the heater in response to the set temperature when the power supply to the heater, the pulse of the pulse waveform current by the heater power supply unit It is characterized by adjusting the amount of power supplied to the heater by adjusting the width or frequency.

In addition, according to the driving control method of the steam thawing apparatus according to the present invention, the controller controls the amount of power supplied to the heater in response to the set temperature when the power supply to the heater, while controlling the switching time of the switching unit through the switching unit It is characterized by adjusting the amount of power supplied to the heater.

According to the present invention, the heater of the steam generator is heated to a steam generation temperature at the time of cold start and at the same time, water is supplied to the steam generator to immediately generate steam to generate steam at high speed during cold start, and the state of the heater Providing information to the user prevents safety accidents during use.

1 is a view showing a steam thaw according to a first embodiment of the present invention.
2 is a view showing a control unit applied to the steam thawing apparatus according to the first embodiment of the present invention.
3 is a view for explaining a driving control method of the steam thaw according to the first embodiment of the present invention.
4 is a view showing a steam thaw according to a second embodiment of the present invention.
5 is a view showing a control unit applied to the steam thawing apparatus according to the second embodiment of the present invention.
6 is a view illustrating a heater power supply unit applied to a steam thaw according to a second embodiment of the present invention.
7 is a view for explaining a driving control method of the steam thaw according to the second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, when the steam thaw is cold-started, the heater of the steam generator is heated and the pump is intermittently operated to draw water from the water supply at a low speed, and the pump continuously operates while the heater reaches the steam generation temperature. By supplying water to the steam generator, by supplying water to the steam generator at the same time as the heating of the heater is completed, it is generated to generate steam at high speed during the cold start.

The steam thawing apparatus 100 according to the first embodiment of the present invention for implementing as described above, as shown in Figure 1, the steam generator 10, the control unit 20, the sensor 30, the switching unit 40 And a pump 50.

The steam generator 10 includes a heater 15 therein, and outputs steam generated by heating the water supplied from the pump 50 by the heater 15. The switching unit 40 switches the power supplied to the heater 15 under the control of the control unit 20.

In addition, the pump 50 is driven under the control of the controller 20 to pump water to be supplied to the steam generator 10, and pumps water from the water supply source 60 to supply the steam generator 10. In addition, the sensor 30 detects the temperature of the heater 15 and applies it to the control unit 20.

The control unit 20 controls the overall driving of the steam thaw 100, and when the cold start of the steam thaw 100, the pump 50 is intermittently operated while heating the heater 15 to stop the water from the water supply source 60 After drawing at low speed for a set time, by continuously operating the pump 50 at the heating completion timing of the heater 15, by supplying water to the steam generator 10 at the same time as the steam generation temperature of the heater 15 is reached It is possible to output steam directly by the steam generator (10).

That is, when cold starting the steam thaw 100, the controller 20 intermittently operates the pump 50 while heating the heater 15 to draw water from the water supply source 60 at a low speed for a predetermined time. During the intermittent operation of the pump 50, the temperature of the heater 15 reaches a temperature at which steam can be generated, and the steam of the heater 15 is generated by continuously operating the pump 50 at the heating completion timing of the heater 15. As soon as the possible temperature is reached, water is supplied to the steam generator 10 to immediately output steam by the steam generator 10.

And, the controller 20 controls the amount of power applied to the heater 15 by controlling the switching time of the switching unit 40 when controlling the power supplied to the heater 15 of the steam generator 10, The heater 15 may be heated to an appropriate temperature without losing power by controlling the amount of power supplied to the heater 15 in response to the set temperature.

The control unit 20 outputs a control signal to the switching unit 40 so that the temperature of the heater 15 can maintain the set temperature without generating the steam while the steam generator 10 generates the steam. By switching the power supply to the heater 15 by the switching unit 40 to control the driving of the heater 15 to prevent overheating and power loss of the heater 15.

In addition, the controller 20 detects the temperature of the heater 15 through the sensor 30 while generating steam by the steam generator 10, and when the set temperature is exceeded, the heater 15 through the switching unit 40. The power supply to the furnace is cut off to prevent overheating of the heater 15. In addition, the controller 20 drives the pump 50 for a predetermined time when the steam thaw 100 stops driving to discharge residual water in the pump 50 and the steam generator 10 to prevent freezing.

As shown in FIG. 2, the control unit 20 includes a microprocessor 21, a display unit 22, a memory 23, an input unit 24, and a matching unit 25.

The microprocessor 21 controls the driving of the steam thaw 100 based on a program stored in the memory 23. The input unit 24 includes a manual operation switch or a keypad to input various commands and information for driving the steam thaw 100 to the microprocessor 21.

The display unit 22 displays a driving state of the steam thaw 100 under the control of the microprocessor 21, and displays a driving state including, for example, whether the heater 15 is overheated. The memory 23 stores a program for controlling the steam thaw 100, stores various data necessary for the control, and provides the program and data to the microprocessor 21.

The matching unit 25 matches the sensor 30, the switching unit 40, and the pump 50 with the microprocessor 21. The matching unit 25 matches the control signal applied from the microprocessor 21, and the switching unit 40 and The pump 50 is delivered to the pump 50, and the detection signal applied from the sensor 30 is matched to the microprocessor 21.

The microprocessor 21 outputs a control signal to the switching unit 40 through the matching unit 25 when the driving start command is input through the input unit 24 to cold start the steam thaw 100. By supplying power to the heater 15 by the 40 to start heating the heater 15, and outputs a control signal to the pump 50 through the matching section 25 to drive the pump 50 intermittently Water is drawn from the water supply 60 at low speed for a set time. In this way, the heater 15 reaches a temperature at which steam can be generated during the set time during which the microprocessor 21 intermittently operates the pump 50.

The microprocessor 21 intermittently operates the pump 50 to draw water from the water supply source 60 at a low speed during the set time, and then outputs a control signal to the pump 50 through the matching unit 25. By continuously supplying water to the steam generator 10 by continuously operating the pump 50, the heater 15 of the steam generator 10 reaches the steam generation temperature and at the same time supplies water to the steam generator 10. To immediately output steam by the steam generator (10).

When the microprocessor 21 controls the power supplied to the heater 15 of the steam generator 10, the microprocessor 21 controls the switching time of the switching unit 40 to adjust the amount of power applied to the heater 15. By controlling the amount of power supplied to the heater 15 in response to the temperature, the heater 15 can be heated to an appropriate temperature without losing power.

In addition, the microprocessor 21 is matched when the temperature of the heater 15 detected from the sensor 30 through the matching unit 25 exceeds the set temperature while generating steam by the steam generator 10. The control unit 25 outputs a control signal through the unit 25 to block the power supply to the heater 15 by the switching unit 40 to prevent overheating of the heater 15.

In addition, when the driving stop command through the input unit 24 is input, the microprocessor 21 drives the pump 50 for a set time to discharge residual water inside the pump 50 and the steam generator 10 to generate freezing waves. prevent. When the driving stop command is input, the user may discharge the residual water inside the pump 50 and the steam generator 10 by releasing the connection of the water supply pipe with the water supply destination 60 and driving the pump 50.

The steam thawing apparatus 100 according to the first embodiment of the present invention having the function as described above is driven as shown in FIG. 3 to generate steam for thawing.

First, when a driving start command is input through the input unit 24 (S111), the microprocessor 21 of the controller 20 outputs a control signal to the switching unit 40 through the matching unit 25 to switch the unit ( 40, power is supplied to the heater 15 to start heating the heater 15 to reach a steam generation temperature (S112).

 In addition, the microprocessor 21 outputs a control signal to the pump 50 through the matching unit 25 to intermittently operate the pump 50 for a set time, so that the water from the water supply source 60 at a low speed for the set time. Pulled in (S113).

As such, the heater 15 reaches a temperature at which steam can be generated during the set time in which the microprocessor 21 intermittently operates the pump 50. After the set time has elapsed, the temperature of the heater 15 is capable of generating steam. At the same time as the temperature is reached, the control signal is output to the pump 50 through the matching unit 25 to continuously operate the pump 50 to supply water to the steam generator 10 (S114), and thus to the steam generator ( In step 10), the water is heated by the heater 15 to a steam generation temperature to generate and output steam (S115).

Thereafter, the microprocessor 21 determines whether a driving stop command is input through the input unit 24 (S116). If the driving stop command is not input, the microprocessor 21 returns to the above-described step S114 to perform a repetitive operation and drive. When the stop command is input, the pump 50 is driven for a set time to discharge residual water inside the pump 50 and the steam generator 10 to prevent freezing (S117), and the operation ends. At this time, when the driving stop command is input, the user may discharge the remaining water in the pump 50 and the steam generator 10 by releasing the connection of the water supply pipe with the water supply destination 60 and driving the pump 50.

In addition, the microprocessor 21, while generating steam by the steam generator 10 in step S115 described above, the switching unit 40 so that the temperature of the heater 15 can maintain the set temperature without exceeding the allowable limit temperature. The control unit outputs a control signal to switch the power supply to the heater 15 by the switching unit 40, thereby controlling the driving of the heater 15 to prevent overheating of the heater 15. In addition, when the heater 15 is overheated, the microprocessor 21 displays the corresponding overheat state through the display unit 22 to prevent the user from causing a safety accident.

In the above description, when the temperature of the heater 15 exceeds the set temperature while the control unit 20 generates steam by the steam generator 10, the power supply to the heater 15 is interrupted to cut off the heater 15. Although it was described as controlling the heater 15 of the steam generator 10 to prevent overheating of), the present invention is not limited thereto, and the user sets a desired steam temperature to the controller 20, and the controller 20 controls the steam. The heater 15 may be heated to correspond to the temperature. As such, when the heater 15 is heated in response to the steam temperature set by the user, since the steam temperature may be adjusted in response to the object of thawing, the thawing process may be performed at an appropriate steam temperature without losing power.

As described above, the steam thaw 100 according to the first embodiment of the present invention heats the heater 15 when cold starting, and intermittently operates the pump 50 for a predetermined time from the water supply source 60. After the water is drawn at low speed, the heater 15 reaches the steam generation temperature and the pump 50 is continuously operated to supply water to the steam generator 10, thereby completing the heating of the heater 15 and At the same time, since the steam is immediately generated by supplying water to the steam generator 10, compared with the prior art which starts supplying water after completion of heating of the heater during cold start, the steam generation time can be shortened.

Meanwhile, as illustrated in FIG. 4, the steam thaw generator 200 according to the second embodiment of the present invention includes a steam generator 110, a controller 120, a sensor 130, a heater power supply 140, and a pump. And 150.

The steam generator 110 includes a heater 115 therein and outputs steam generated by heating water supplied from the pump 150 by the heater 115. The heater power supply unit 140 adjusts the power supplied to the heater 115 under the control of the controller 120, and adjusts the amount of power supplied to the heater 115. Preferably, the heater power supply 140 adjusts the amount of power supplied to the heater 115 by adjusting the pulse width or frequency of the pulse waveform current applied to the heater 115 under the control of the controller 120.

In addition, the pump 150 is driven under the control of the controller 120 to pump water to be supplied to the steam generator 110, and to pump the water from the water supply source 160 to supply the steam generator 110. In addition, the sensor 130 detects a temperature of the heater 115 and applies it to the controller 120.

The control unit 120 controls the overall operation of the steam thaw 200, and when the cold start of the steam thaw 200, the pump 150 is intermittently operated while heating the heater 115, the water from the water supply source 160 After pulling at a low speed for a set time, by continuously operating the pump 150 at the heating completion timing of the heater 115, by supplying water to the steam generator 110 at the same time the steam generating temperature of the heater 115 reaches It is possible to output steam directly by the steam generator (110).

That is, when cold starting the steam thaw 200, the controller 120 intermittently operates the pump 150 while heating the heater 115 to draw water from the water supply source 160 at a low speed for a predetermined time. During the intermittent operation of the pump 150, the temperature of the heater 115 reaches a temperature at which steam can be generated, and the steam of the heater 115 is generated by continuously operating the pump 150 at the heating completion timing of the heater 115. As soon as the possible temperature is reached, water is supplied to the steam generator 110 to immediately output steam by the steam generator 110.

In addition, the control unit 120 outputs a control signal to the heater power supply unit 140 while generating steam by the steam generator 110 to control the power supplied to the heater 115 through the heater power supply unit 140. In this case, by adjusting the pulse width or frequency of the pulse waveform current applied to the heater 115 by the heater power supply 140 to adjust the amount of power supplied to the heater 115, the heater 115 in response to the set temperature. By precisely adjusting the amount of power supplied to the) to heat the heater 115 without unnecessary power consumption.

The controller 120 detects the temperature of the heater 115 through the sensor 130 while generating steam by the steam generator 110, and when the set temperature is exceeded, the heater 115 through the heater power supply 140. ) To prevent power supply to the heater 115 by cutting off the power supply. In addition, the controller 120 drives the pump 150 for a set time when the steam thaw 200 stops driving to discharge residual water in the pump 150 and the steam generator 110 to prevent freezing.

As shown in FIG. 5, the control unit 120 includes a microprocessor 121, a display unit 122, a memory 123, an input unit 124, and a matching unit 125.

The microprocessor 121 controls the driving of the steam thaw 200 based on a program stored in the memory 123. The input unit 124 includes a manual operation switch or a keypad to input various commands and information for driving the steam thaw 200 to the microprocessor 121.

The display unit 122 displays the driving state of the steam thaw 200 under the control of the microprocessor 121, and for example, displays the driving state including whether the heater 115 is overheated or the like. The memory 123 stores a program for controlling the steam thaw 200, stores various data necessary for the control, and provides the program and data to the microprocessor 121.

The matching unit 125 matches the sensor 130, the heater power supply unit 140, and the pump 150 with the microprocessor 121, and matches the control signal applied from the microprocessor 121 to supply the heater power supply unit 140. And the detection signal applied from the sensor 130 are matched to the microprocessor 121.

The microprocessor 121 outputs a control signal to the heater power supply unit 140 through the matching unit 125 when the driving start command is input through the input unit 124 to cold start the steam thaw 200. The power supply unit 140 supplies power to the heater 115 to start heating the heater 115, and outputs a control signal to the pump 150 through the matching unit 125 to interrupt the pump 150. It drives and draws water from the water supply source 160 at low speed for a predetermined time. As such, the heater 115 reaches a temperature at which steam can be generated during the set time during which the microprocessor 121 intermittently operates the pump 150.

The microprocessor 121 intermittently operates the pump 150 to draw water from the water supply source 160 at a low speed for a predetermined time, and then outputs a control signal to the pump 150 through the matching unit 125. By continuously supplying water to the steam generator 110 by continuously operating the pump 150, the heater 115 of the steam generator 110 reaches the steam generating temperature and simultaneously supplies water to the steam generator 110. To immediately output steam by the steam generator (110).

In addition, the microprocessor 121 matches when the temperature of the heater 115 detected from the sensor 130 through the matching unit 125 exceeds the set temperature while generating steam by the steam generator 110. By outputting a control signal to the heater power supply unit 140 through the unit 125 to block the power supply to the heater 115 by the heater power supply unit 140 to prevent overheating of the heater 115.

The microprocessor 121 outputs a control signal to the heater power supply 140 while generating steam by the steam generator 110 to control power supplied to the heater 115 through the heater power supply 140. In this case, by adjusting the pulse width or frequency of the pulse waveform current applied to the heater 115 by the heater power supply unit 140 to adjust the amount of power supplied to the heater 115 to correspond to the set temperature. Since the heating of) can be finely controlled, the heater 115 can be heated without unnecessary power consumption.

In addition, when the driving stop command through the input unit 124 is input, the microprocessor 121 drives the pump 150 for a set time to discharge the residual water inside the pump 150 and the steam generator 110 to generate freezing waves. prevent. When the driving stop command is input, the user may discharge the residual water inside the pump 150 and the steam generator 110 by releasing the connection of the water supply pipe with the water supply source 160 and driving the pump 150.

In addition, the heater power supply unit 140, as shown in FIG. 6, includes an input unit 141, a rectifier 142, a pulse generator 143, and an output unit 145.

The input unit 141 converts the voltage of the commercial AC power input to the rectifier 142. The rectifier 142 rectifies and converts AC power applied from the input unit 141 into DC power and outputs the DC power to the pulse generator 143. In addition, the pulse generator 143 receives the DC power from the rectifier 142 to generate a pulse to output the current of the pulse waveform to the output unit 145, but according to the control signal applied from the control unit 120 pulse waveform The amount of power applied to the output unit 145 is adjusted by adjusting the pulse width or frequency of the current. In addition, the output unit 145 supplies a pulse waveform current applied from the pulse generator 143 to the heater 115, and converts the pulse waveform current into a voltage usable by the heater 115.

The heater power supply 140 configured as described above is supplied to the heater 115 by supplying a pulse waveform current to the heater 115 according to a control signal from the controller 120, and controlling the pulse width or frequency of the corresponding pulse waveform current. Since the amount of power can be finely controlled, the controller 120 can adjust the amount of power supplied to the heater 115 in response to the set temperature, thereby heating the heater 115 without excessive power consumption.

The steam thaw 200 according to the second embodiment of the present invention having the function as described above is driven as shown in FIG. 7 to generate steam for thawing.

First, when a driving start command is input through the input unit 124 (S211), the microprocessor 121 of the control unit 120 outputs a control signal to the heater power supply unit 140 through the matching unit 125 to supply the heater power. The power supply unit 140 supplies power to the heater 115, but adjusts the amount of power supplied to the heater 115 to start heating the heater 115 to reach a steam generation temperature (S212).

 In addition, the microprocessor 121 outputs a control signal to the pump 150 through the matching unit 125 to intermittently operate the pump 150 for a set time, so that the water from the water supply source 160 at a low speed for the set time. Pulled in (S213).

As such, the heater 115 reaches a temperature at which steam can be generated during the set time during which the microprocessor 121 intermittently operates the pump 150. After the set time has elapsed, the temperature of the heater 115 may generate steam. At the same time as reaching the temperature, by outputting the control signal to the pump 150 through the matching unit 125 to supply the water to the steam generator 110 by continuously operating the pump 150 (S214), the steam generator ( The water is heated by the heater 115 to the steam generation temperature at 110 and generates and outputs steam (S215).

Thereafter, the microprocessor 121 determines whether a driving stop command is input through the input unit 124 (S216). If the driving stop command is not input, the microprocessor 121 returns to the above-described step S214 and performs a repeating operation. When the stop command is input, the pump 150 is driven for a set time to discharge residual water inside the pump 150 and the steam generator 110 to prevent freezing (S217), and the operation ends. In this case, when the driving stop command is input, the user may discharge the remaining water in the pump 150 and the steam generator 110 by releasing the connection of the water supply pipe with the water supply source 160 and driving the pump 150.

In addition, while the microprocessor 121 generates steam by the steam generator 110 in step S215 described above, the temperature of the heater 115 detected from the sensor 130 through the matching unit 125 may set the set temperature. When exceeding, the control signal is output to the heater power supply unit 140 through the matching unit 125 to cut off the power supply to the heater 115 by the heater power supply unit 140 to prevent overheating of the heater 115. . When the heater 115 is overheated, the microprocessor 121 displays the corresponding overheating state through the display unit 122 to prevent the user from causing a safety accident.

In the above description, when the temperature of the heater 115 exceeds the set temperature while the control unit 120 generates steam by the steam generator 110, the power supply to the heater 115 is cut off to prevent the heater 115. It is described as controlling the heater 115 of the steam generator 110 to prevent overheating of, but is not limited to this, the user sets the desired steam temperature to the control unit 120, the control unit 120 is the steam The heater 115 may be heated to correspond to the temperature. As such, when the heater 115 is heated in response to the steam temperature set by the user, since the steam temperature may be adjusted in response to the thawing target, the thawing process may be performed at an appropriate steam temperature without losing power.

As described above, the steam thaw 200 according to the second embodiment of the present invention heats the heater 115 when cold starting, and intermittently operates the pump 150 for a predetermined time from the water supply source 160. After the water is drawn at a low speed, the heater 115 reaches the steam generating temperature and the pump 150 is continuously operated to supply water to the steam generator 110, thereby completing the heating of the heater 115. At the same time, since steam is immediately generated by supplying water to the steam generator 110, compared to the prior art that starts supplying water after completion of heating of the heater at the time of cold start, the steam generation time can be shortened.

The present invention is not limited to the above description, and those skilled in the art can change the present invention in various forms without departing from the technical spirit of the present invention. It will be said that such modifications fall within the technical scope of the present invention.

The present invention may be usefully applied to a steam thawing machine that generates steam to thaw. According to the present invention, the heater of the steam generator is heated to a steam generation temperature at the time of cold start and at the same time, water is supplied to the steam generator to immediately generate steam to generate steam at high speed during cold start, and the state of the heater Providing information to the user prevents safety accidents during use.

10, 110; Steam generators 15 and 115; heater
20, 120; Control units 21 and 121; Microprocessor
22, 122; Display sections 23 and 123; Memory
24, 124; Inputs 25 and 125; The matching portion
30, 130; Sensor 40; The switching unit
50, 150; Pump 140; Heater power supply

Claims (17)

In the steam thawing apparatus having a steam generator for receiving water and heated by a heater to generate steam for thawing,
A sensor for detecting a temperature of the heater and applying it to a controller;
A pump for pumping water supplied to the steam generator under control of the controller;
A switching unit for switching the power supply to the heater according to the control of the controller;
At start-up, the switching unit supplies power to the heater to heat the heater to intermittently operate the pump to draw water from the water supply at a low speed for a predetermined time, and then continuously operate the pump to operate the steam at a temperature capable of generating steam. And a control unit for controlling the water supply to the steam generator upon reaching the steam generator.
The method of claim 1,
The control unit,
An input unit which inputs various driving commands and information to the microprocessor by manual operation;
A display unit for displaying a driving state of the steam thaw under the control of the microprocessor;
A memory for storing a program for control, storing general data necessary for control, and providing the program and data to a microprocessor;
A matching unit for matching the sensor, the switching unit and the pump to a microprocessor;
The control unit outputs a control signal to the switching unit through the matching unit according to the driving instruction through the input unit and supplies power to the heater by the switching unit to output the control signal to the pump through the matching unit while heating the heater, thereby intermittently operating the pump. And a microprocessor for continuously driving the pump by drawing water from the supply source at a low speed for a predetermined time and then outputting a control signal to the pump through the matching unit.
The method of claim 2,
And the microprocessor switches power supply to the heater by the switching unit so that the temperature of the heater can maintain a set temperature without exceeding an allowable limit temperature.
The method of claim 2,
And the microprocessor drives the pump for a predetermined time when the driving stop command is input through the input unit to discharge residual water inside the pump and the steam generator.
The method of claim 2,
And the microprocessor controls the switching unit to heat the heater in response to a steam temperature set through an input unit.
The method of claim 2,
The microprocessor controls the amount of power supplied to the heater by controlling the switching time of the switching unit in response to the temperature set through the input unit.
In the steam thawing apparatus having a steam generator for receiving water and heated by a heater to generate steam for thawing,
A sensor for detecting a temperature of the heater and applying it to a controller;
A pump for pumping water supplied to the steam generator under control of the controller;
A heater power supply unit controlling an amount of power supplied to the heater by controlling a pulse width or frequency of a pulse waveform current applied to the heater according to the control of the controller;
At start-up, the heater is supplied with power to the heater to heat the heater, and the pump is intermittently operated to draw water from the water supply at a low speed for a predetermined time, and then the pump is continuously operated to allow the heater to generate steam. And a control unit for controlling water supply to the steam generator at the same time as it reaches.
The method of claim 7, wherein
The control unit controls the heater power supply in response to a set temperature, characterized in that for adjusting the amount of power supplied to the heater.
9. The method according to claim 7 or 8,
The control unit,
An input unit which inputs various driving commands and information to the microprocessor by manual operation;
A display unit for displaying a driving state of the steam thaw under the control of the microprocessor;
A memory for storing a program for control, storing general data necessary for control, and providing the program and data to a microprocessor;
A matching unit for matching the sensor, the heater power supply and the pump to a microprocessor;
The control signal is output to the heater power supply unit through the matching unit according to the driving instruction through the input unit to supply power to the heater by the heater power supply unit to heat the heater, and output the control signal to the pump through the matching unit to intermittently operate the pump. And a microprocessor configured to draw water from the water supply at a low speed for a predetermined time, and then output a control signal to the pump through the matching unit to continuously operate the pump.
10. The method of claim 9,
The heater power supply unit,
An input unit for converting a voltage of an input commercial AC power source;
A rectifier for rectifying AC power applied from the input part and converting the AC power into DC power;
A pulse generator for generating a pulse by receiving DC power from the rectifier and outputting a current of a pulse waveform, and adjusting an amount of power output by adjusting a pulse width or frequency of a pulse waveform current according to a control signal;
And an output unit converting the pulse waveform current output from the pulse generator into a voltage usable by the heater and outputting the converted voltage to the heater.
In the drive control method of the steam thawing machine,
Heating the heater by supplying power to the heater when the controller receives a driving start command;
Outputting a control signal to the pump to control the pump for a predetermined time to drive the pump to draw water from the water supply at a low speed for a predetermined time;
And driving the pump to continuously supply the water to the steam generator by continuously operating the pump to generate and output steam by the steam generator.
12. The method of claim 11,
And if the control unit receives a driving stop command during steam generation, driving the pump for a predetermined time, discharging the residual water inside the pump and the steam generator, and ending the operation.
12. The method of claim 11,
Detecting, by the controller, a temperature of the heater while steam is generated;
The control unit further comprises the step of preventing the overheating of the heater by blocking the power supply to the heater when the temperature of the heater exceeds the set temperature.
12. The method of claim 11,
Setting the steam temperature received by the controller;
And controlling the power supply to the heater to heat the heater to correspond to the steam temperature.
12. The method of claim 11,
The control unit further comprises the step of controlling the power supply to the heater so that the temperature of the heater to maintain the set temperature without exceeding the allowable limit temperature.
The method according to any one of claims 11 to 15,
The control unit adjusts the amount of power supplied to the heater in response to the set temperature when the power supply to the heater, by adjusting the pulse width or frequency of the pulse waveform current by the heater power supply to adjust the amount of power supplied to the heater Driving control method of the steam thawing apparatus, characterized in that.
The method according to any one of claims 11 to 15,
The control unit adjusts the amount of power supplied to the heater in response to the set temperature at the time of supplying power to the heater, by controlling the switching time of the switching unit to adjust the amount of power supplied to the heater through the switching unit Drive control method.

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