KR200368314Y1 - Heater apparatus for heating a plating tank - Google Patents

Abstract

The disclosed plating apparatus heater apparatus is provided with a control unit for controlling the supply of electrical energy, a water temperature sensing unit for connecting one end to the control unit to sense the solution temperature in the plating bath and a heat generating unit for heating the solution in the plating bath connected to the control unit, The heat generating unit and a heating element for converting the electrical energy supplied from the control unit into thermal energy; A heat sensor for detecting overheating of the heating element; A heating element in which a plurality of hollows are formed to closely insert the heating element and the heat sensor; And a cover accommodating the heat transfer body and filled with magnesium oxide between the heat transfer body and the heat transfer body. The heating apparatus for a plating bath having such a structure heats the solution in the plating bath by using a magnesium oxide heat transfer body having a good heat transfer rate, so that the solution can be quickly heated, and the heat retention of the magnesium oxide heat transfer body is that of conventional air. Better than the holding power can provide an effect to reduce the supply of electrical energy to the heating element.

Description

Heater apparatus for heating a plating tank

The present invention relates to a heater device, and more particularly, to a plating bath heater device that can quickly heat a solution contained in a bath such as a plating bath, and can maintain the heat generated temperature of the heating element for a long time.

Generally, tanks such as aquariums and plating baths provide an optimal environment for inhabiting ornamental fish and maintain a constant temperature of the solution at the time of plating, so that heater devices are contained to obtain high quality plating products. Will be maintained.

As a heater device used to maintain the water temperature of such a tank, a structure as shown in FIG. 1 has been generally employed.

Referring to the drawings, the heater device is located in the control unit 10, the heating element 20 is connected to the control unit 10 to generate heat, and spaced apart from the heating element 20 is connected to the control unit 10 The water temperature sensor 30 for sensing the temperature of the water or the solution, the heat sensing unit 21 for sensing the temperature of the heating element 20 and the cover 40 for receiving the heating element 20 and the heat sensing unit 21 Include.

The controller 10 includes a case 11 and a control unit 12 installed in the case 11, and the control unit 12 receives electricity from a condenser (not shown). A plug 14 is connected to the current supply line 13.

The heating element 20 is wound in the form of a coil and is connected to the control unit 12 of the control unit 10 to receive electricity from the control unit 12 to generate heat.

The water temperature detector 30 senses the temperature of the water or the solution and transmits the temperature to the control unit 12.

The heat sensing unit 21 is connected to the control unit 10 to sense the temperature of the heating element 20, and if the heating element 20 is overheated or does not generate heat, the state in the control unit 12 of the control unit 10 To pass.

The cover 40 prevents the heating element 20 and the heat sensing part 21 from contacting with water or a solution, and serves as a medium for transferring heat generated from the heating element 20 to water or a solution.

The heating device having such a structure detects the water temperature in the water temperature sensing unit 30 contained in the aquarium or the plating tank and sends the water temperature to the control unit 10. Then, the control unit 10 transmits the electrical energy to the heating element 20, the heating element 20 converts the received electrical energy into thermal energy to heat the external water or plating solution. At this time, when a process of heating the external water or the plating liquid in the heating element 20, first, the air in the cover 40 is heated, and the heated air heats the external water or the plating liquid through the cover 40. If the water or solution contained in the aquarium or the plating bath is lowered below the heat generating part by evaporation or leakage and the heat generating element 20 is overheated, the heat sensing unit 21 adjacent to the heat generating element 20 detects the control unit 10. ). Then, the control unit 10 stops the supply of electric energy to the heating element 20 to prevent overheating of the heating element 20. If the heating element 20 is left unheated, the aquarium or the plating bath is made of a flammable material, which increases the possibility of a fire.

However, since the conventional heater device heats water or a solution by the heating element 20 installed in the cover 40, first, the air inside the cover 40 is heated, and then water or solution through the cover 40. Heat it. However, when the air is first heated in this way, when water or a solution is heated by the heat transfer medium, the heat transfer rate is lowered, the heating time is slowed, and the heat holding power of the heated air is weak, thereby continuously supplying electric energy. There is a problem to be done. In addition, when the heating element 20 is overheated, the heat sensing unit 21 recognizes this and stops the supply of electric energy from the control unit 10 to the heating element 20, but has a problem that it cannot be easily recognized from the outside.

The present invention was created in view of the above necessity, and an object of the present invention is to provide an improved heating apparatus for a plating vessel to reduce the heating time of a solution contained in the plating vessel and the like, and to maintain the heat holding power of the heat transfer medium for a long time.

In addition, another object of the present invention is to provide a heating apparatus for a plating bath that the heating element is overheated to easily recognize the interruption of the supply of electrical energy from the outside.

1 is a perspective view showing a conventional heater device,

Figure 2 is a perspective view showing a heater device for a plating bath according to an embodiment of the present invention,

3 is a cross-sectional view showing a heater for a plating bath according to line III-III of FIG.

4 is a front perspective view showing a heat generating unit of the plating apparatus heater apparatus of FIG.

<Description of the symbols for the main parts of the drawings>

100 ... control unit 110 ... alarm unit

200 ... Water temperature sensor 210 ... Water temperature sensor

220 ... water temperature sensor lead 300 ... heating element

310 ... heating element 320 ... hollow

330 ... heating element 331 ... heating element lead

340 ... Thermal sensor 341 ... Thermal sensor lead

350 ... cover 400 ... plating bath

The present invention for achieving the above object, the control unit for controlling the supply of electrical energy, one end is connected to the control unit is connected to the water temperature sensing unit and the control unit for detecting the solution temperature in the plating bath solution in the plating bath. A heating apparatus for a plating bath provided with a heating unit for heating, the heating unit comprising: a heating element for converting electrical energy supplied from the control unit into thermal energy; A heat sensor for detecting overheating of the heating element; A plurality of hollows are formed to form a heating element and the heating element and the heat sensor is in close contact; and a cover for accommodating the heating element, the magnesium oxide is filled between the heating element.

Here, the water temperature detection unit is preferably inserted into the hollow of the heat transfer body.

In addition, it is preferable that the said heat-transfer body is magnesium oxide.

In addition, the control unit is preferably connected to the heat detection sensor includes a warning device that operates when the heating element emits heat energy above a set temperature.

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

2 and 3 illustrate a plating apparatus heater apparatus according to an embodiment of the present invention.

Referring to the drawings, the plating apparatus heater apparatus includes a control unit 100, the water temperature sensing unit 200 and the heat generating unit 300.

The control unit 100 is connected to a power source (not shown), the water temperature sensing unit 200 and the heating unit 300, respectively. The control unit 100 receives the electric energy from the power source to control the operation mechanism of the present invention. In addition, the temperature of the solution 410 in the plating bath 400 is received from the water temperature sensing unit 200 to supply electric energy according to the temperature set in the heat generating unit 300. Then, by receiving the contents recognized by the heat sensor 340 in the heat generating unit 300 to be described later controls the supply of electrical energy to the heat generating unit 300. In addition, the control unit 100 is provided with an alarm device 110 to notify the overheating state of the heating element 330 to be described later. The alarm device 110 may be used at least one of the alarm sound generator or the alarm lamp.

The heating unit 300 includes a heating element 310, a heating element 330 inserted into the heating element 310, and a heating element lead 331 for transmitting electrical energy from the control unit 100 to the heating element 330. , A heat sensor 340, a heat sensor lead 341, and a cover 350.

The heat exchanger 310 is made of magnesium oxide having a better heat transfer rate than gas, and as shown in FIG. 4, a hollow 320 in which a heat sensor 340 is inserted is formed, and the heat sensor 340 is formed. At least one hollow 320 is radially formed around the hollow 320 to be inserted, so that the heating element 330 is closely inserted.

The heating element 330 is tightly inserted into the hollow 320 of the heating element 310 and is connected to the controller 100 by the heating element lead 331. The heating element 330 converts the electrical energy received from the control unit 100 into thermal energy, and the thermal energy converted by the heating element 330 heats the solution 410 in the plating bath 400 to an appropriate temperature.

The heat sensor 340 is inserted into the hollow 320 formed in the central portion of the heat transfer body 310, it is connected to the control unit 100 by the heat sensor lead 341. The heat sensor 340 detects whether the heating element 330 is overheated and transmits the contents to the controller 100.

The cover 350 has a good heat transfer rate, is made of titanium, stainless steal, teflon, and the like, and has a high corrosion resistance. The cover 350 protects the heating element 310 into which the heating element 330 and the heat detection sensor 340 are inserted so as not to be exposed to the solution 410 in the plating bath 400.

In addition, the heat transfer body 310 and the cover 350 containing the heat transfer body 310 are filled with magnesium oxide powder 311 to further improve heat transfer. In addition, when the heating element 310 is bent to a desired shape, the heating element 310 made of magnesium oxide may be broken, but the magnesium oxide powder 311 is filled between the heating element 310 and the cover 350. Therefore, the broken gap is filled with the magnesium oxide powder 311, which has no effect on heat transfer. Therefore, the heat transfer body 310 can be freely deformed.

The water temperature detection unit 200 is inserted into the hollow 320 formed in the heat transfer body 310, the water temperature sensor 210 and the water temperature sensor to recognize the temperature of the solution 410 contained in the plating bath 400 It consists of a water temperature detection sensor lead 211 for transmitting the temperature recognized by the control unit 100. Here, the water temperature sensing unit 200 is inserted into the hollow 320 in the heat transfer body 310 to simplify the structure of the heater apparatus for the plating bath, which is conventionally configured separately from the heat generating unit.

Plating bath heater device having a structure as described above is a device that is partially immersed in the solution 410 in the plating bath 400 to heat the solution 410, look at the operation process, first the plating in the water temperature sensing unit 200 The temperature of the solution 410 in the bath 400 is recognized and transmitted to the controller 100. Then, the control unit 100 receives the electrical energy from the power supply to supply the electrical energy to the heating element 330 to maintain the temperature of the solution 410 preset. The heating element 330 converts the supplied electrical energy into thermal energy to heat the solution 410 in the plating bath 400 by using the magnesium oxide heating element 310 as a medium. However, if the level of the solution 410 in the plating bath 400 is lower than the heating portion, or when the solution 410 is depleted due to the crack of the plating bath 400, or the solution outside the water temperature sensing unit 200. When the 410 is heated or the solution 410 is evaporated due to prolonged use, when the heater does not generate heat due to other scales and overheats, the plating tank 400 made of a flammable material may cause a fire. have. In order to prevent this, when the heating element 330 is overheated, the heat detection sensor 340 recognizes this and transmits it to the control unit 100. The control unit 100 stops or reduces the supply of electrical energy to the heating element 330. In addition, in order to easily recognize the overheating phenomenon of the heating element 330 transmitted to the control unit 100, the control unit 100 transmits it to the alarm device 110 to operate an alarm sound or an alarm lamp.

Therefore, according to the present invention, it is possible to quickly heat the solution in the plating bath by using the magnesium oxide heat transfer body having good heat transfer rate and heat retention power, and the overheating of the heating element can be easily recognized by the alarm device.

As described above, the heater for built-in overheat prevention sensor of the present invention provides the following effects.

First, the solution in the plating bath is heated by the medium of magnesium oxide heat-transfer having good heat transfer rate, so that the solution can be heated quickly. Also, the heat-resistance of the magnesium oxide heat-transfer is better than that of conventional air. It is more economical because it can reduce supply.

Second, when the heating element is overheated due to when the solution in the plating tank is lower than the heating portion of the heater device, the alarm device is activated so that the overheating state of the heating element can be easily recognized from the outside.

Third, since the water temperature sensing unit is inserted into the hollow in the heat transfer body, it is possible to simplify the structure of the conventional plating apparatus heater device which is configured separately from the heat generating unit.

It is understood that the invention is not limited to that described above and illustrated in the drawings and that many more modifications and variations are possible within the scope of the following claims.

Claims (4)

In the heating apparatus for a plating bath provided with a control unit for controlling the supply of electric energy, a water temperature sensing unit for connecting one end to the control unit for sensing the solution temperature in the plating bath and a heating unit connected to the control unit for heating the solution in the plating bath. In The heating unit, A heating element for converting electrical energy supplied from the control unit into thermal energy; A heat sensor for detecting overheating of the heating element; A plurality of hollows are formed, the heating element into which the heating element and the heat sensor are inserted; And And a cover containing the heat transfer body and a magnesium oxide filled therein with the heat transfer body. The method of claim 1, The water temperature sensing unit is a bath for a plating bath, characterized in that inserted into the hollow of the heat transfer body. The method of claim 1, The heating element is a plating apparatus heater device characterized in that the magnesium oxide. The method of claim 1, The control unit is connected to the heat detection sensor heater device for a plating bath, characterized in that it comprises a warning device to operate when the heating element emits heat energy above a set temperature.