KR100930707B1 - A heating unit using heating generator of cyclone type - Google Patents

Abstract

PURPOSE: A heating device and a hot water supplying device using a cyclone type thermo-generator and a secondary heater are provided to save the energy and cost for heating by heating fluid with a secondary heater first and then heating the fluid with the cyclone type thermo-generator after the power supply of the secondary heater is cut. CONSTITUTION: A heating device using a cyclone type thermo-generator and a secondary heater comprises a fluid input pipe(100), a fluid intake pump(200), a heater(300) and a fluid discharge pipe(400). The heater comprises a tubular housing, a temperature sensor and a MICOM(350). The tubular housing is cylindrical or polygon shape. The thermo-generator is inserted into the inner side of the housing. The secondary heater is mounted in the output side of the thermo-generator and is combined in the inside of the housing. The temperature sensor is inserted into the inner side of the housing. The temperature of the fluid flowing within the housing is checked. The MICOM controls the operation of the pump device and the secondary heater according to a result of the temperature sensor.

Description

Heating device and hot water supply device using cyclone type heat generating means and auxiliary heater {A Heating Unit Using Heating Generator of Cyclone Type}

The present invention relates to a heating device and a hot water supply device using a cyclone-type heat generating means and an auxiliary heater, and in particular, to induce the flow of the fluid in the form of a cyclone, while at the same time the heat is generated by the natural properties of the water while the fluid swirls, After reaching the set temperature using the auxiliary heater, the power of the auxiliary heater is cut off, and the fluid is heated using only the cyclone type heat generating device, thereby minimizing the power to reach the heating. The present invention relates to a heating device and a hot water supply device using a device and an auxiliary heater.

The heating method is largely classified into a small stove wall heater that burns fuel by heating it directly, a radiator is placed indoors, and a steam hot water heating method that heats steam and hot water made by an outdoor boiler therein. (熱) The warm air heating method that sends the air with high temperature such as gas, steam, hot water, and electric heat to the room, and put the pipe in the ceiling of the wall, and send the hot water in the wall to increase the surface temperature of the ceiling. There is a radiant heating method for heating.

Among these heating devices, the hot water heating device warms the floor and indoor air of a bedroom, living room, or room by circulating the hot water coil heated by a hot water boiler in winter.

Ondol heating using the hot water boiler as described above is the hot water heated by the heater of the hot water boiler is branched from the hot water distributor to each room through the hot water pipe, the hot water coil embedded in the floor of each room to heat the hot water on the floor and indoors In this way, the temperature or floor temperature of each room is controlled by one thermostat connected to the boiler.

Figure 1 shows a typical hot water heating device, the heating water supplied through the water supply pipe 1 is heated by a heating means (boiler) 7 heating pipe through the circulation pump 6 and the water supply distributor 3 (Excel pipes, etc.) are circulated, and the circulated heating water is returned through the return distributor 4. And the hot water heated to the desired temperature flows to the heating pipe to be heated.

However, such a heating device uses water as a heat medium liquid to store heat, so the boiler must be operated at all times in order to maintain a heating state.

The present invention is to solve the above problems, by combining the cyclone type heat generating device and the auxiliary heater as a heating means to be heated together with the auxiliary heater up to the set temperature, and then to heat the fluid using the cyclone type heat generating device. In this way, the heating through the auxiliary heater is made only at the beginning, and after that, the cyclone type heat generating device maintains the heating temperature, and thus an object of the present invention is to provide an economical heating device that does not need to continuously heat the fluid.

As a means for achieving the above object,

The present invention is the fluid input pipe 100 is input to the heating device for the water circulated in the heating pipeline to be heated again; A fluid input pump device 200 connected to an output end of the fluid input pipe and supplied with a fluid, and receiving external power to rotate an impeller to circulate the fluid; As a means for receiving and heating the fluid output from the fluid input pump device 200, the pipe-shaped housing 310 of the cylindrical or polygonal tubular shape, and inserted and coupled to the inside of the housing 310, but the pump device for fluid input Cyclone-type heat generating device 320 is installed on the output line side of the housing 310 is inserted and coupled to the inside of the housing 310, auxiliary heater 330 is installed on the output side of the cyclone-type heat generating device and the housing 310 A temperature sensing sensor 340 inserted into the inside of the housing to check a temperature of the fluid flowing inside the housing, and a microcomputer 350 controlling the operation of the auxiliary heater and the fluid input pumping device according to the result of the temperature sensing sensor. The heating device 300 is made; It is characterized in that the fluid output pipe 400 is connected to the heating device 300 for outputting the heated hot water output through the heating device 300 to the hot water line.

In addition, the cyclone heat generator 320,

The pressure adjusting cap 321 is installed in a staircase shape and has a space, and has a polygonal panel-shaped upper plate 322 having a spiral protrusion on its side, and a lower plate 324 having a polygonal panel shape and having a discharge hole 323 at a lower portion thereof. And a cyclone panel 325 inserted between the upper plate 322 and the lower plate 324 and spirally inserted into a central shape from the corners of the upper plate and the lower plate coupling portion to the discharge hole 323 of the lower plate. It is characterized in that it comprises an output pipe 326 is installed in the extension, and the pressure release hole 327 for releasing the pressure generated by the flow of water is formed in the center of the pressure adjusting cap.

In addition, the space for installing the fluid input pump device, the space for installing the heat generating device, the space for installing the auxiliary heater and the heat exchanger is separated into a partition for the hot water housing 310a; A fluid input pump (200) embedded in one side space of the hot water housing (310a) for circulating fluid through a pipe; A cyclone type heat generating device (320) installed in the upper space of the hot water housing (310a) and connected to an output side of the fluid input pump (200) to generate heat while passing the fluid; An auxiliary heater 330 installed at an output side of the heat generator; A temperature sensor 340 installed in a space into which the auxiliary heater 330 is inserted to check a temperature; A microcomputer (350) for controlling the operation of the auxiliary heater and the fluid input pumping device according to the result of the temperature sensor; Installed in the auxiliary heater space portion is characterized in that it comprises a heat exchanger 500 of the pipe shape for discharging hot hot water through the cold cold water.

When the apparatus of the present invention is used, the heating device is manufactured by combining the cyclone type heat generating means and the auxiliary heater, thereby assisting the heating with the auxiliary heater up to a predetermined temperature, and then heating the fluid using the cyclone type heat generating device. There is an advantage that does not need to continuously heat the fluid, and this has the effect of economical heating and hot water equipment that minimizes the cost.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

2 to 6 show a first embodiment of the present invention,

Figure 2 is a perspective view of the heating apparatus using the auxiliary heater and the cyclone-type heat generating means of the present invention.

3 is an internal configuration diagram of the heating apparatus of FIG. 2.

4 is a perspective view of a heat generating device of the present invention.

5 is an exploded perspective view of a heat generating device of the present invention.

6 is a conceptual view of the heat generation operation of the present invention,

FIG. 7 illustrates a second embodiment of the present invention, and is a block diagram of a hot water supply device using a cyclone-type heat generating device and an auxiliary heater of the present invention.

Hereinafter, the first embodiment will be described sequentially.

(First embodiment)

The first embodiment relates to a heating device using a cyclone-type heat generating device and an auxiliary heater, the components are largely the fluid input pipe 100, the fluid input pump device 200, the heating device 300, It consists of a fluid output pipe 400.

The fluid input pipe 100 is a pipe that is erected in a vertical form and is a pipe through which water passes when water is pumped by the operation of the fluid input pump device 200. The fluid input pipe 100 is a line input to a heating device in order to reheat the water circulated in the heating pipeline.

The fluid input pump device 200 is connected to an output end of the fluid input tube to receive a fluid, and receives external power to rotate an impeller so that the fluid is circulated.

The operating range of the fluid input pump device 200 can be appropriately adjusted depending on the circulation strength of the water. If the pump device is rotated at a high speed, the circulation speed of the water is increased by increasing the circulation speed of the water and slowing the operation speed of the pump device. . In the present invention, by properly adjusting the rotational speed of the fluid input pump device 200 can be used to circulate the water at the optimized speed.

The heating device 300 is a cylindrical or polygonal tubular housing 310 and the cyclone-type heat generating device 320 is inserted into the housing 310 is coupled to the inside of the output line of the pump for fluid input And an auxiliary heater 330 inserted into the housing 310 and installed at an output side of the heat generator, and a temperature sensing device for checking a temperature of a fluid inserted into the housing 310 and flowing inside the housing 310. Sensor 340, and the microcomputer 350 for controlling the operation of the auxiliary heater and the fluid input pump device in accordance with the result of the temperature sensor.

That is, the microcomputer 350 receives the temperature value from the auxiliary heater 330 and stops the operation of the auxiliary heater 330 when the fluid flowing through the housing 310 exceeds the set temperature. Only 200 is continuously driven so that only the circulation of water passing through the cyclone-type heat generating device 320 is possible. As described above, when the fluid input pump device 200 drives the water circulation action, heat is continuously generated by the heat generator 320, so that the temperature of the fluid can be maintained without using an auxiliary heater 330. As a result, the energy required for separately operating the auxiliary heater 330 is not required.

If the fluid input pump device 200 and the cyclone heat generator 320 are not used at this time, since the heater 330 must be continuously operated at a predetermined time, it requires a lot of electrical energy. When using the fluid input pump device 200 and the cyclone type heat generating device 320 as in the present invention, the auxiliary heater 330 is used only when the heating water is initially raised to a predetermined temperature, and the set temperature is reached. When the power supply of the auxiliary heater 330 is stopped and only the fluid input pump device 200 and the cyclone type heat generator 320 are used to heat the heating water, thereby maximizing energy efficiency.

Looking specifically at the cyclone-type heat generating device 320, the pressure control cap 321 is installed in a staircase type with a polygonal panel-shaped top plate 322 having a space portion and a spiral protrusion formed on the side, and a polygonal panel shape The cyclone panel is formed between the lower plate 324 having a discharge hole 323 at the bottom, and inserted between the upper plate 322 and the lower plate 324 and spirally inserted in the center direction from the corners of the upper and lower plate coupling portions. 325 and an output pipe 326 extending to the discharge hole 323 of the lower plate. In addition, a pressure release hole 327 for releasing the pressure generated by the flow of water is formed in the center of the pressure adjusting cap.

The fluid output pipe 400 is a pipe which is installed on the upper side of the heating device 300 and disposed in a form perpendicular to the heating device 300. It is usually made by combining the cylindrical pipe and the water passing through the heating device 300 to be transported through the vertically arranged fluid output pipe 400.

Looking at the overall operation of the present invention as follows.

First, when the fluid input pump device 200 is operated, water is transferred to the pump device through the bypass pipe 410 or the fluid input pipe 100, and then the housing 310 of the heating device 300 through the output line. Flows into).

And water flowing into the housing 310 of the heating device 300 is inserted through one end of the housing 310 of the heating device 300, wherein the heat generating device 300 is the upper plate 322 and the lower plate ( 324 and cyclone panel 325 and closed by top plate 322 and bottom plate 324 so that water passes through cyclone panel 325 from the border between top plate 322 and bottom plate 324. In this case, since a plurality of cyclone-type panels 325 are installed between the upper plate 322 and the lower plate 324, the fluid passes through the cyclone-type panel 325 while generating heat according to the nature of the discharge hole 323. Will exit to the bottom.

Since the heating device 300 of the present invention is not a vertically erected structure, but a horizontally arranged side by side, the fluid flowing by the fluid input pump device 200 has a top plate 322 as shown in the drawing. The lower plate 324 flows from the right side to the left side and flows to the right through the discharge hole 323 and the output pipe 326 of the lower plate connected to the lower plate 324 to generate heat.

At this time, the pressure control cap 321 formed on the upper plate serves to adjust the pressure according to the flow of the fluid, the pressure changes inside the heat generating device 300 when the fluid swirls and passes through the cyclone-type panel 325 At this time, by the pressure adjusting cap 321 to properly adjust the pressure to enable a smooth fluid flow. In addition, a pressure releasing hole 327 is formed in the upper portion of the pressure adjusting cap 321 to release the vacuum pressure generated when the fluid proceeds in a cyclone shape so that the pressure inside the cyclone type heat generating device 320 is properly adjusted. It can be adjusted.

The fluid that has passed through the cyclone heat generator 320 passes through the fluid input pipe and the fluid input pump device 200 through the heating hose through the output pipe to circulate the cyclone heat generator 320. do.

On the other hand, the auxiliary heater 330 is mounted inside the housing 310 of the heating device 300, when the heating device is initially operated, power is supplied to the auxiliary heater to heat the fluid at a high speed. That is, the auxiliary heater 330 together with the cyclone-type heat generating device 320 operates to heat the fluid within a short time, and check the heating temperature with the sensor 340 to exceed the predetermined temperature, for example, 40 degrees. The operation of 330 is stopped and the fluid is heated only by using the cyclone type heat generator 320.

Then, the temperature of the fluid passing through the heating device 300 is no longer dropped or the temperature is lowered at a very slow rate, it is not necessary to operate the auxiliary heater 330 separately.

As a result, in the present invention, the cyclone-type heat generating device 320 is installed in the housing 310 of the heating device 300, but heat is generated as the fluid flows between the cyclone-type panels 325 through a plurality of spaces from the outside. In addition, the auxiliary heater 330 is used to initially heat the fluid flowing inside the housing 310 at a high speed by using electrical energy, and after the fluid is heated to the set temperature, the cyclone-type heat generator 320 By heating the fluid using only), it provides the advantage of being able to heat up quickly and maintaining the heating state with little energy.

(Second embodiment)

The second embodiment relates to a hot water supply device using the cyclone-type heat generator 320 and the auxiliary heater 330, the space portion for installing the fluid input pump device, the space portion for installing the heat generator; The space for installing the auxiliary heater and the heat exchanger is divided into a partition for the hot water housing (310a), and a fluid input pump device for circulating the fluid through the pipe is built in one side of the hot water housing (310a) ( 200 and a cyclone-type heat generator 320 installed in the upper space of the hot water housing 310a and connected to the output side of the fluid input pump device 200 to generate heat while passing the fluid; Auxiliary heater 330 installed on the output side of the cyclone-type heat generating device, a temperature sensor 340 for checking the temperature is installed in the space in which the auxiliary heater 330 is inserted, and installed in the auxiliary heater space It is made to be contained to the heat exchanger 500 of the pipe-like, by passing a cold water through the input side of the heat exchanger 500 and the hot water can be taken from the output side of the heat exchanger (500).

As in the first embodiment, the cyclone-type heat generating device 320 has a polygonal panel-shaped upper plate 322 having a space portion having a pressure control cap 321 installed in a staircase shape and having a spiral protrusion formed on a side thereof, and a polygon. It is made of a panel shape and is inserted between the lower plate 324 having a discharge hole 323 in the lower portion, the upper plate 322 and the lower plate 324 and is inserted and coupled in a spiral shape from the corners of the upper and lower plate coupling portion in the center direction It consists of a cyclone panel 325 and an output pipe 326 extending in the central hole of the lower plate. In addition, a pressure releasing hole 327 for releasing pressure generated by the flow of water is formed in the center of the pressure adjusting cap.

Also, in this case, after the auxiliary heater 330 and the microcomputer 350 are heated to the set temperature using the auxiliary heater as in the first embodiment, the temperature is checked by the sensor 340, and the temperature is higher than the set temperature. The fluid is heated using only the cyclone-type heat generator 320 to enable the use of hot hot water through the heat exchanger 500.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. That is, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the scope of the technical spirit of the present invention by these embodiments. Therefore, the protection scope of the present invention should be interpreted by the claims below, and all technical ideas within the equivalent scope will be construed as being included in the scope of the present invention.

1 is a block diagram of a conventional hot water heater.

Figure 2 is a perspective view of the heating apparatus using the heater and the cyclone-type heat generating means of the present invention.

3 is an internal configuration diagram of the heating apparatus of FIG. 2.

Figure 4 is a perspective view of the heat generating means of the present invention.

5 is an exploded perspective view of the heat generating means of the present invention.

6 is a conceptual view of the operation of the heat generating means of the present invention.

7 is a block diagram of a beverage supply apparatus using the heater and the cyclone-type heat generating means of the present invention.

Explanation of symbols on the main parts of the drawings

100: fluid input tube

200: pump device for fluid input

300: heating device

310: housing

320: cyclone type heat generating device

321: pressure adjusting cap

322: tops

323: discharge hole

324: lower plate

325: cyclone panel

326: output pipe

327: pressure release hole

330: heater

340: temperature sensor

350: micom

400: fluid output tube

500: heat exchanger

Claims (4)

A fluid input pipe (100) input to a heating device so that water circulated in the heating pipeline is heated again; A fluid input pump device 200 connected to an output end of the fluid input pipe and supplied with a fluid, and receiving external power to rotate an impeller to circulate the fluid; Means for heating and receiving the fluid output from the fluid input pump device 200, and a cylindrical housing or a tubular tubular housing (310); A cyclone heat generator 320 inserted into and coupled to the inside of the housing 310 and installed at an output line side of the pump device for fluid input; An auxiliary heater 330 inserted into the housing 310 and installed at an output side of the heat generator; A temperature sensor 340 inserted into the housing 310 and checking a temperature of the fluid flowing inside the housing 310; The heating device (300) comprising a microcomputer (350) for controlling the operation of the auxiliary heater and the fluid input pumping device according to the result of the temperature sensing sensor; The cyclone-type heat generating means and the heating using the auxiliary heater, characterized in that it is connected to the heating device 300 comprises a fluid output pipe 400 for outputting the heated hot water output through the heating device 300 to the hot water line Device. The method of claim 1, The cyclone heat generator 320, The pressure adjusting cap 321 is installed in a staircase shape and has a space, and has a polygonal panel-shaped upper plate 322 having a spiral protrusion on its side, and a lower plate 324 having a polygonal panel shape and having a discharge hole 323 at a lower portion thereof. And a cyclone panel 325 inserted between the upper plate 322 and the lower plate 324 and spirally inserted into a central shape from the corners of the upper plate and the lower plate coupling portion to the discharge hole 323 of the lower plate. Cyclone-type heat generating means and auxiliary heater, characterized in that it comprises an output pipe 326 is extended and installed, the pressure release hole 327 formed in the center of the pressure control cap for releasing the pressure generated by the flow of water Heating system using. A hot water housing 310a in which a space portion in which a fluid input pump device is installed, a space portion in which a heat generator is installed, and a space portion in which an auxiliary heater and a heat exchanger are installed are separated into partitions; A fluid input pump (200) embedded in one side space of the hot water housing (310a) for circulating fluid through a pipe; A cyclone type heat generating device (320) installed in the upper space of the hot water housing (310a) and connected to an output side of the fluid input pump (200) to generate heat while passing the fluid; An auxiliary heater 330 installed at an output side of the heat generator; A temperature sensor 340 installed in a space into which the auxiliary heater 330 is inserted to check a temperature; A microcomputer (350) for controlling the operation of the auxiliary heater and the fluid input pumping device according to the result of the temperature sensor; The cyclone-type heat generating means and the hot water supply device using the auxiliary heater, characterized in that it comprises a heat exchanger 500 of the pipe shape is installed in the auxiliary heater space to pass the cold cold water to discharge hot hot water. The method of claim 3, wherein The cyclone-type heat generating device 320, the pressure control cap 321 is installed in a staircase shape, the polygonal panel-shaped top plate 322 having a space portion and formed a spiral protrusion on the side, and made of a polygonal panel shape and A lower plate 324 having a discharge hole 323 therein, and a cyclone panel 325 inserted between the upper plate 322 and the lower plate 324 and inserted and coupled in a spiral shape from the corners of the upper and lower plate coupling portions in a helical direction. And an output pipe 326 extending in the discharge hole 323 of the lower plate, and a pressure releasing hole 327 formed at the center of the pressure adjusting cap to release pressure generated by the flow of water. Hot water supply device using a cyclone-type heat generating means and auxiliary heater characterized in that.

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