KR20220058210A - Immersion heaters - Google Patents

Abstract

An immersion heater according to the present invention includes a heating pipe having a heat wire embedded therein, a sensing pipe having a sensor provided therein to detect heat, and a body part connected to ends of the heating pipe and the sensing pipe and having a PCB board provided therein to control the temperature of the heat wire. The immersion heater comprises: an overcurrent detection part configured on the PCB board and detecting an overcurrent higher than a current value when a conductor is in contact with the heating pipe and touches water; and a heat wire power cutoff part which cuts off power to the heat wire when the overcurrent detection part detects an overcurrent. When the overcurrent occurs due to the conductor contacting the heating pipe, the overcurrent detection part detects the overcurrent, and when the overcurrent occurs for a set time, an overcurrent detection time control part detects the overcurrent and cuts off the power to the heating wire, thereby solving a dangerous and inconvenient problem that the power is cut off whenever the conductor is in contact, and a worker has to unplug and plug in again while wearing wet gloves.

Description

Submersible Heaters {IMMERSION HEATERS}

The present invention relates to an underwater heater, and more particularly, to an underwater heater that shuts off after a certain period of time without shutting off the power immediately when a conductor or the like temporarily touches it.

In general, an underwater heater is used to conveniently heat a large amount of water or a heating object such as a liquid chemical or aqueous solution contained in a water tank, container, or water tank, such as a basin, to a predetermined temperature, and has high thermal efficiency and does not cause pollution. Because of its simple structure, it is widely used for industrial and home use.

At this time, the conventional submersible heater spirally winds the lower part of the heating tube having a built-in heating element that emits thermal energy according to the power supply, and the both ends are coupled through the insert formed on the lower surface of the control box to be connected to the power terminal. And a temperature control unit for adjusting the temperature of the heating object is provided on the upper surface of the control box, a lamp indicating whether the heating element is operating or not is provided, and between both ends of the heating tube, the temperature of the heating object is sensed to control the operation of the heating element It is provided so that the water temperature sensing tube to be controlled is in equilibrium with the heating tube and does not come into contact with each other.

A technology related to such an underwater heater is disclosed in Korean Patent Registration No. 1274646.

Patent Document 1 has a problem in that when a conductor comes into contact with a heater pipe, the power is cut off as a result of a short circuit, or the temperature rises due to overcurrent and is exposed to the risk of fire.

Korea Patent No. 1274646 (2013.06.07)

The present invention has been devised in view of the above points, and the solution of the present invention is to delay the power cut-off for a set time when a conductor or the like touches the heating pipe, and to cut off the power when the set time is exceeded. It is intended to provide

The underwater heater according to the present invention for achieving the above object, a heating pipe having a built-in heating wire therein, a sensing pipe having a sensor to detect heat therein, and a heating wire connected to the end of the heating pipe and the sensing pipe A submersible heater consisting of a main body with a built-in PCB board to control temperature. Overcurrent detection that is configured on the PCB board and detects an overcurrent that is higher than the current value when a conductor comes into contact with the heating pipe and comes into contact with water wealth; and a hot wire power cut-off unit that cuts off power to the hot wire when the over-current sensing unit detects an overcurrent.

It may further include an overcurrent detection time control unit for detecting and adjusting the overcurrent detection time in the overcurrent detection unit to output a power cutoff signal to the hot wire power cutoff unit.

The overcurrent detection time control unit may provide a power cutoff signal to the hot wire power cutoff unit when the overcurrent of the overcurrent detection unit is maintained for 40 to 60 seconds.

According to the present invention, when an overcurrent occurs due to contact of a conductor with a heating pipe, the overcurrent detection unit detects it, and when the overcurrent generation is maintained for a set time, the overcurrent detection time control unit detects this and cuts off the power of the heating wire so that the conductor is in contact As the power is cut off every time it is done, there is an effect that can solve the dangerous and inconvenient problem that the worker has to unplug and plug in and out while wearing wet gloves.

1 is a perspective view showing the overall configuration of an underwater heater according to the present invention.
Figure 2 is a block diagram showing the control means of the underwater heater according to the present invention.
Figure 3 is a block diagram showing the control process of the underwater heater according to the present invention.
Figure 4 is a partial enlarged view showing a state in which the sensing pipe of the underwater heater according to the present invention is provided so that the length can be adjusted.

The above objects, features and other advantages of the present invention will become more apparent by describing preferred embodiments of the present invention in detail with reference to the accompanying drawings. Hereinafter, an underwater heater according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing the overall configuration of the underwater heater according to the present invention, Figure 2 is a block diagram showing the control means of the underwater heater according to the present invention, Figure 3 is a control process of the underwater heater according to the present invention It is a structural block diagram showing, Figure 4 is a partial enlarged view showing a state in which the sensing pipe of the underwater heater according to the present invention is provided so that the length can be adjusted.

1 to 4 , the underwater heater 100 of the present invention includes a body portion 110 , a heating pipe 120 and a sensing pipe 130 .

As shown in FIG. 1 , the main body 110 has ends of the heating pipe 120 and the sensing pipe 130 fixed to the lower portion, respectively, and a PCB substrate 112 is provided therein. A plug for power supply is electrically connected.

In addition, the main body 110 is provided with a power terminal rod (not shown in the drawing) to which both ends of the heating wire 122 are electrically connected while being positioned inside the heating pipe 120 .

That is, the upper end of the power terminal rod is fixed to the inside through the bottom surface of the main body 110 , and the lower end is connected to both ends of the heating wire 122 .

The PCB board 112 has a temperature control unit 114 that can control the temperature by the lever 1140, unlike the existing one in which the temperature controller is connected in a modularized state separately from the board, so that the structure can be simplified, It delays the cut-off of power for a set time even when a conductor or the like touches the surface of the heating pipe 120, and includes a control unit that cuts off the power when the set time is exceeded. In addition, numerical values for each temperature are displayed along the periphery of the lever 1140 , and the temperature is output through the upper display window (not shown in the drawing).

The control unit is configured as a circuit on the PCB board 112 as shown in FIG. 2, and includes an overcurrent detection unit 1120, an overcurrent detection time control unit 1122, and a hot wire power cutoff unit 1124, the underwater of the present invention When the heater 100 is positioned in water and operates normally, a high amount of power is sensed while a conductor such as a metal is in contact with the amount of power, and when the high amount of power is detected for more than a set time, the power is cut off to prevent danger.

The overcurrent detection unit 1120 is configured on the PCB substrate, and when a conductor such as an iron is in contact with the heating pipe 120 and an overcurrent higher than the normal current value when the conductor comes into contact with water occurs, it detects it.

At this time, the normal current value is preset in the circuit.

The overcurrent detection time control unit 1122 detects the overcurrent detection time in the overcurrent detection unit 1120 and adjusts the detection time to output a power cutoff signal to the hot wire power cutoff unit 1124 .

At this time, when the overcurrent detection time control unit 1122 maintains the overcurrent of the overcurrent detection unit 1120 for 40 to 60 seconds and the temperature of the heating wire 122 rises to a range of 190 to 195° C., the hot wire power cutoff unit for fire prevention Provides a power-off signal to (1124).

The heating wire power cutoff unit 1124 cuts off power applied to the heating wire 122 inside the heating pipe 120 when the overcurrent detection unit 1120 detects an overcurrent.

As shown in FIG. 1 , the heating pipe 120 is formed in the form of a hollow metal tube, and a coil-shaped heating wire 122 is embedded therein.

In this case, the heating pipe 120 is preferably formed of a metal material such as titanium, iron, tantalum, zirconium, or stainless steel, which is low in weight, corrosion resistance and thermal conductivity, corrosion resistance, chemical resistance, and the like.

And by filling the inside of the heating pipe 120 with a filler such as magnesium oxide (Mgo) having excellent thermal conductivity and insulation to surround the heating wire 122, the thermal efficiency according to the conversion of electrical energy into thermal energy is increased, and external physical shock It is also sturdy and can be properly processed into various shapes according to the purpose.

And the heating pipe 120 is formed by bending the end submerged in water into a U-shape or a trellis shape.

The heating wire 122 is installed inside the heating pipe 120 and has a heating structure that generates heat by receiving power, and is provided with any one of heating elements such as a nichrome wire, a carbon heating element, a ceramic heating element, and a tungsten wire.

In addition, the heating wire 122 is provided with a fuse in the middle and is set to lose its function when the set temperature (100° C. to 190° C.) is exceeded, and the power cut state is maintained at the function loss temperature.

The sensing pipe 130 has an upper portion fixed to the lower portion of the main body 110 as shown in FIG. 1 , and a heat sensor (not shown in the drawing) connected to the PCB board 112 and wires inside the sensing pipe 130 is provided. It is built-in.

And it is possible to sense the temperature by the heat sensor built into the sensing pipe (130).

Referring to FIG. 4 , the sensing pipe 130 is adjustable in length. To this end, in a state in which the sensing pipe 130 is vertically divided into an upper pipe 1320 and a lower pipe 1340, the lower part of the upper pipe 1320 and the upper part of the lower pipe 1340 adjacent to each other have opposite spiral directions. A length adjusting part l360 is provided, which forms a protrusion, is screwed to the spiral protrusion of the upper pipe 1320 and the lower pipe 1340, and forms a spiral hole at both ends of the inner circumferential surface in which the spiral direction is opposite.

Therefore, when the length adjusting unit l360 is rotated in either direction, the distance between the upper pipe 1320 and the lower pipe 1340 screwed to both ends of the length adjusting unit l360 is reduced or widened, and the lower pipe 1340 . The end of the heating pipe 120 may be moved in the direction of the heating pipe 120 to sense the temperature.

Furthermore, in the upper pipe 1320 and the lower pipe 1340 , the opposite ends of the first and second length adjusting units l360 are tightly coupled to the upper and lower surfaces to prevent loosening in a state in which they are spirally fastened to the length adjusting unit l360 . Loosening prevention parts 1362 and 1364 are provided.

At this time, the first and second loosening preventing parts 1362 and 1364 are formed in a nut shape in which a spiral hole is formed, respectively, and the spiral direction is formed in the opposite direction, and the spiral protrusion of the upper pipe 1320 is fixed to the upper surface of the length adjusting unit l360. and the spiral protrusion of the lower pipe 1340 is fixed to the lower surface of the length adjustment unit l360.

As described above, the power cut-off process during abnormal operation of the underwater heater 100 of the present invention will be described as follows.

First, in the underwater heater 100 of the present invention, a part of the heating pipe 120 and the sensing pipe 130 is immersed in water to heat the contained water. No overcurrent is detected through the unit 1120 .

Next, when a conductor or the like comes into contact with the surface of the heating pipe 120, the power of the existing submersible heater is cut off immediately, so power must be supplied again. When the temperature of the heating wire 122 rises to a range of 190 to 195° C. with a delay by a degree, the power applied to the heating wire 122 is cut off through the hot wire power cutoff unit 1124 .

That is, when an overcurrent is generated as a conductor or the like comes into contact with the surface of the heating pipe 120 , the overcurrent detecting unit 1120 detects it ( S10 ).

And, when the overcurrent detection time reaches the existing range of about 40 seconds through the overcurrent detection time control unit 1122, a power cutoff signal is output to the hot wire power cutoff unit 1124 (S20).

Thereafter, the power applied to the hot wire 122 is cut off through the hot wire power cutoff unit 1124 ( S30 ).

And within 40 seconds, which is the power cut-off criterion, the conductor that has touched the surface of the heating pipe 120 is separated.

Moreover, even if the overcurrent detection time reaches 40 seconds and the power supply is cut off by the hot wire power cut-off unit 1124, if the power supply plug (not shown in the drawing) is removed and plugged in again to reset, the submersible heater 100 will not operate again. do.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can realize that the present invention may be embodied in other specific forms without changing its technical spirit or essential features. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

100: water heater 110: body part
112: PCB board 1120: overcurrent detection unit
1122: overcurrent detection time control unit 1124: hot wire power cutoff unit
120: heating pipe 130: sensing pipe

Claims (3)

A heating pipe having a built-in heating wire inside, a sensing pipe having a sensor to detect heat inside, and a body part with a PCB board embedded therein to control the temperature of the heating wire while connected to the ends of the heating pipe and the sensing pipe As a heater,
an overcurrent sensing unit configured on the PCB substrate and detecting an overcurrent that is higher than a current value when a conductor comes into contact with the heating pipe and comes into contact with water; and
Underwater heater comprising a; a hot wire power cutoff unit that cuts off the power of the hot wire when the overcurrent detection unit detects an overcurrent.
The method of claim 1,
Underwater heater characterized in that it further comprises an overcurrent detection time control unit for detecting and adjusting the overcurrent detection time in the overcurrent detection unit to output a power cutoff signal to the hot wire power cutoff unit.
The method of claim 1,
The overcurrent detection time control unit is an underwater heater, characterized in that when the overcurrent of the overcurrent detection unit is maintained for 40 to 60 seconds, it provides a power cutoff signal to the hot wire power cutoff unit.

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