KR200378278Y1 - Heating apparatus with boiler and warm air circulator functiong - Google Patents

Abstract

The present invention relates to a heater for heating the interior of a building, and relates to a heater for heating the interior using a liquid heat fluid heated in a boiler. The present invention, and the boiler 10 for supplying a liquid heat fluid to a high temperature; One end and the other end is connected to the boiler 10, embedded in the floor or wall of the room, the heating pipe 12 of the closed loop type to heat the room while circulating the heated thermal fluid of the boiler 10 and ; It includes; a radiator 20 for supplying the heat of the heat fluid heated in the boiler 10 to the room. This invention, since the heating pipe 12 heats the building structure in the room at the same time, the radiator 20 heats the air in the room, there is an effect that can be three-dimensional heating the room in a short time.

Description

Heater and boiler combined heater {HEATING APPARATUS WITH BOILER AND WARM AIR CIRCULATOR FUNCTIONG}

The present invention relates to a heater for heating the interior of a building, and relates to a heater for heating the interior using a liquid heat fluid heated in a boiler.

In general, heaters are roughly classified into boilers and warmers, which are ondol heaters. Here, the boiler heats the liquid heat fluid, and then heats the interior of the heated heat fluid through a heating pipe embedded in a building structure (floor or wall) of the building. At this time, the liquid thermal fluid is mostly water. Then, the warmer heats the air, and then supplies the heated air to the room to heat the room. At this time, the hot air heater heats the air with a firearm or a heat transfer coil.

Such boilers and hot air heaters are classified according to heat sources, and in the case of boilers, main parts are oil boilers, gas boilers, briquette boilers, and the like.

Such a boiler and a hot air heater exhibit only their respective functions due to their design characteristics. That is, the boiler heats only the liquid liquid and supplies it to the heating pipe, thereby heating the room, and the hot air heater only heats the air to heat the room.

However, as the boiler takes a long time to heat the room to a suitable temperature, in the majority of houses or buildings that use the boiler, a separate hot air heater is provided so that the heat is supplied to the room while the boiler heats the room to a proper temperature. There is a problem that must be purchased and used. In addition, in the case of using only a hot air heater, there is a problem that a boiler must be provided because fuel costs are excessively required.

In other words, since the boiler or the hot air heater has only its own function, the majority of houses or buildings have to purchase the boiler or the hot air heater for heating, and accordingly, the purchase cost is excessively expensive. However, there are problems that fuel costs are different.

In conclusion, in order to heat a building structure and air in the room at the same time, not only a boiler or a hot air heater should be provided at the same time, but also have a problem in that they operate with different fuels.

The present invention has been made to solve the above-mentioned conventional problems, and to provide a hot air heater and a combined heater heater for heating while simultaneously heating the building structure and air in the room by using a heated heat fluid. Purpose.

The object of the present invention is a boiler for heating and supplying a liquid thermal fluid to a high temperature; One end and the other end is connected to the boiler, embedded in the floor or wall of the room, the heating pipe of the closed loop type heating the room while circulating the heated thermal fluid of the boiler; And a radiator for supplying heat of the heat fluid heated in the boiler to the room.

Here, the radiator, for example, having an air inlet and an air outlet on one side and the other side, the tubular case having a hollow; A bypass loop of a closed loop type disposed in the hollow of the case and bypassing a part of the heated heating medium supplied from the boiler to the heating pipe and circulating it back to the boiler; And a blower fan that blows air into the bypass pipe and discharges heat of the bypass pipe heated by the heated heat medium to the air outlet of the case.

This, the present invention, is integrally connected to the air outlet of the case, it is necessary to further comprise a; at least one duct to direct the heat discharged from the air outlet to the set position of the room.

Hereinafter, with reference to the accompanying drawings, a hot air heater and a combined heater according to the present invention will be described as follows, attached FIG. 1 is a plan view showing the configuration of a hot air heater and a combined heater according to an embodiment of the present invention, FIG. 2 is a plan view showing the configuration of the radiator shown in FIG.

As shown in FIG. 1, the hot air heater and the combined heater according to the embodiment of the present invention include: a boiler 10 for heating a liquid thermal fluid; A heating loop 12 of a closed loop type connected to the boiler 10; It includes; a radiator 20 for supplying heat to the room.

The boiler 10 heats water to a high temperature and supplies it to the heating pipe 12. At this time, as shown in the heating pipe 12, one end and the other end is connected to the boiler 10 takes a closed loop form. Therefore, the heating pipe 12 is supplied with the heated water of the boiler 10 from one end and circulated, and then sent back to the boiler 10 through the other end. Of course, the boiler 10 recirculates the water recirculated in a cooled state while being circulated and resupply the heating pipe 12.

As shown, the heating pipe 12 is zigzag embedded in the floor (1a) and / or not shown wall of the interior (1), which can be referred to as the building structure of the building. Accordingly, the heating pipe 12 heats the building structure while circulating the heated water of the boiler 10. Thus, the room 1 is heated to an appropriate temperature.

At this time, the radiator 20 supplies the heat of the heat fluid heated in the boiler 10 to the room. Such a radiator 20 includes, for example, a tubular case 22 having a hollow as shown in FIG. 2; A bypass pipe 24 through which the heated thermal fluid of the boiler 10 circulates; And a blowing fan 26 for blowing air into the bypass pipe 24.

As described above, the case 22 is preferably composed of a rectangular hexahedron. In this case 22, the side is sealed and at one side and the other side is opened, and each air inlet 22a and air outlet 22b are provided at one side and the other side.

As described above, one side end of the bypass pipe 24 is connected to one side end of the above-described heating pipe 12. That is, the bypass pipe 24 is a branch pipe branched from the heating pipe 12. One side end of the bypass tube 24 may be connected to one side end of the heating pipe 12 by a T-shaped elbow (not shown).

And the other end of the bypass pipe 24 is directly connected to the boiler 10, as shown. Of course, one end of the bypass pipe 24 is not connected to the heating pipe 12, it may be directly connected to the hot water supply of the boiler (10). In addition, the other end of the bypass 24 may not be directly connected to the boiler 10, but may be connected to the other end of the heating pipe 12. At this time, the bypass pipe 24 circulates only a part of the water heated in the boiler 10, it is preferable to form smaller than the diameter of the heating pipe (12).

This bypass tube 24 is installed to take the form of a zigzag inside the case 22, as shown. Therefore, the bypass pipe 24 receives a portion of the water heated in the boiler 10 through the heating pipe 12, circulates bypassed along the pipeline, and then re-sends the boiler 10 again.

The bypass tube 24 may be configured as shown in the figure, alternatively, may be configured in plurality. If a plurality of the plurality of bypass tubes 24 are provided, the plurality of bypass tubes 24 may be stacked or superimposed. Of course, when configuring a plurality of, the total diameter of the plurality of bypass pipes 24 should be determined in consideration of the diameter of the heating pipe 12.

Here, one side end of the above-described heating pipe 12 is the inlet side into which the water heated in the above-described boiler 10 is introduced, and the other end of the heating pipe 12 cools the water to the boiler 10 while circulating the heating pipe 12. Supply outlet side.

As described above, the blowing fan 26 is installed at one side of the case 22. Such a blowing fan 26 fixes the lower part not shown by welding or bolting to the bottom of the case 22. Therefore, the blower fan 26 is located in the air inlet 22a side of the case 22. As shown in FIG. Such a blower fan 26 blows air toward the air outlet 22b side of the case 22 due to the installation position.

On the other hand, the filter F as shown in FIG. 2 is provided in the air inlet 22a or the air outlet 22b of the case 22. As shown in FIG. In this case, the filter F may be installed at both the air inlet 22a and the air outlet 22b, as shown in the drawing. Alternatively, the filter F may be installed at only one of the air inlet 22a and the air outlet 22b. have. Such a filter F is provided in a state of shielding the air inlet 22a and the air outlet 22b. Therefore, the filter F filters the impurities in the air via the air inlet 22a or the air outlet 22b during the operation of the blower fan 26.

The filter F may be made of a nonwoven fabric, or alternatively, may be made of a strainer made of fiber, plastic, or metal. Alternatively, it may be composed of an antibacterial filter mainly composed of charcoal, loess, ceramics and the like. Furthermore, these can be superimposed and it can also be combined.

On the other hand, the air outlet 22b of the case 22 is provided with a duct D, as shown in FIG. This, the duct (D) is connected to the room in need of supply of warmth. Here, the interior in which the warmth needs to be supplied may be, for example, an office divided into a bedroom, a living room, a health room, or a curtain wall.

If warm air is supplied to a plurality of rooms or offices, it is necessary to configure the duct D as a plurality of ducts D2 as shown in FIG. 2. Such a plurality of ducts D2 are arranged in a plurality of rooms or offices respectively. Therefore, the plurality of ducts D2 respectively supply heat to the plurality of rooms or offices.

At this time, the distribution duct D1 as shown in the figure can be provided between the plurality of ducts D2 and the case 22. The distribution duct D1 distributes the heat discharged from the air outlet 22b of the case 22 into the plurality of ducts D2 and at the same time connects the case 22 and the plurality of ducts D2. do.

At this time, the duct (D) is preferably provided with an on-off valve (V) as shown in Figure 2 for opening and closing the passage. Such an open / close valve V may be configured as a cock valve (not shown) such as a faucet. Alternatively, it may be configured as a disc disk valve (not shown). Alternatively, the valve may also be configured as a flat valve (not shown). In addition, the switching valve (V) may be configured to automatically operate by a switch or a remote control not shown. That is, the on-off valve V can also be configured to operate electrically. Here, the installation method and form, and the operation of the on-off valve (V), and can be easily understood by those skilled in the art, detailed description thereof will be omitted.

As shown in the drawing, the on-off valve V is preferably installed at the air inlet side of the duct D. The on-off valve V can open and close the passage of the duct D completely, and can open and close little by little. Therefore, the flow rate of the duct D can be adjusted by the opening and closing valve (V). Here, the illustrated on-off valve (V) is installed one by one in the above-described plurality of ducts (D).

On the other hand, the upper end of the air outlet (22a) of the case 22 can be installed by bolting the ringer trap 28, as shown enlarged in FIG. The ringer trap 28 is a box-type tank for storing water. The ringer trap 28 has at least one nozzle N as shown on the bottom surface. At this time, the through hole 22c corresponding to the nozzle N should be formed in the case 22. Of course, the through hole 22c may be formed in the upper surface of the duct D as necessary.

The ringer trap 28 supplies water droplets to the air outlet 22a located inside the case 22 through the nozzle N and the through hole 22c of the case 22 or the duct D. At this time, the ringer trap 28 supplies water droplets in the form of a rock water such as Ringer of Ringer's bottle. That is, it drops while dropping "smart".

The reason why the ringer trap 28 can supply the water droplets in the form of fresh water is because of the diameter of the nozzle N. That is, because the diameter of the nozzle (N) has a size that can supply water in the form of fresh water. Of course, the diameter of the nozzle (N) should be specifically designed in consideration of the weight of the water stored in the ringer trap 28, that is, the water pressure so that the water droplets can be supplied in the form of fresh water.

The applicant of the present invention forms a plurality of fine holes to constitute the nozzle (N). At this time, the hole was formed to a diameter of about 0.01mm to 0.03mm. Thus, according to the configuration of the nozzle (N), the water stored in the ringer trap 28 is collected a little bit under the nozzle (N) of the ringer trap 28, and then discharged in the form of droplets.

The supply time of such water droplets is about 30 seconds is appropriate. That is, the ringer trap 28 supplies water droplets with a predetermined time difference. Here, the supply time is determined by the diameter of the nozzles N, the holes constituting the nozzles N, or the number of these holes.

On the other hand, a plurality of plate-shaped heat radiation fins 24a, as shown in FIG. 2, may be integrally installed in the aforementioned bypass tube 24. The heat dissipation fins 24a preferably use a metal thin plate such as a copper material, a zinc material, a stainless steel material or an alloy material, and particularly preferably a metal thin plate made of an aluminum material.

The bypass tube 24 penetrates through the heat radiating fins 24a in a zigzag manner, as shown. The heat dissipation fins 24a may be fixed to the bypass pipe 24 by welding. Such a heat radiation fin 24a radiates heat to the outside of the bypass tube 24 heated by water supplied from the boiler 10.

On the other hand, the radiator 20 may be controlled by a switch or a remote controller not shown. Such a switch or a remote controller may be separately provided. Alternatively, a switch or a remote controller of the boiler 10 may be used. Of course, such a switch or remote control of the boiler 10 is obviously to be electrically connected to the blowing fan 26 of the radiator 20.

The switch or the remote controller may be configured to not only control the operation of the radiator 20 but also to control the air volume of the blower fan 26. That is, it is preferable that the switch or the remote controller not only turns the blower fan 26 ON / OFF, but also can be configured to control the rotational speed in multiple stages.

In addition, the switch or the remote controller may be configured to turn on / off the boiler 10 and the radiator 20 together in a single operation. That is, when the ON / OFF button of the switch or the remote control is pressed, the boiler 10 and the radiator 20 may be configured to be ON / OFF together.

Thus, if the switch or the remote control is configured, the temperature of the room heated by the radiator 20 can be arbitrarily conveniently adjusted. In particular, it is possible to adjust the temperature more conveniently indoors using the remote control.

Since such a switch and a remote control are easy structures, detailed description is abbreviate | omitted.

Referring to Figure 2 describes the operation of the heater and the combined heater according to the embodiment of the present invention configured as described above. First, the user presses an ON button of a switch or a remote controller not shown to operate the boiler 10 and the radiator 20. Accordingly, the boiler 10 heats and supplies water to a high temperature, and the radiator 20 operates the blower 26 to blow air. At this time, the radiator 20 may be operated separately from the boiler 10. However, in the present description it will be described that working with the boiler 10 as an example.

Subsequently, the boiler 10 supplies the water heated to a high temperature to the heating pipe 12 embedded in the building structure (floor or wall) of the room, and the heating pipe 12 circulates the water to build the building structure. After heating, the water is returned to the boiler 10 again. At this time, some of the water heated in the boiler 10 is supplied to the bypass pipe 24 connected to the heating pipe 12, circulated along the bypass pipe 24, and then sent back to the boiler 10 do.

As a result, the bypass pipe 24 is heated to a high temperature. At this time, the heat dissipation fins 24a dissipate the heat of the bypass pipe 24 and discharge the heat dissipated by the blower fan 26 to the air outlet 22b of the case 22. At this time, the heat discharged by the blowing fan 26, that is, the air inside the case 22 is air purified by the filter F.

Thus, the heat discharged from the case 22 is supplied to the room via the duct D connected to the air outlet 22b side of the case 22. At this time, when the duct (D) is composed of a distribution duct (D1) and a plurality of ducts (D2), the heat discharged from the case 22 to the plurality of ducts (D2) through the distribution duct (D1) Distributed supply. If the plurality of ducts D2 are configured as three, for example, as shown in the drawing, and arranged in the living room, the room, and the other side of the room, the heat of the radiator 20 is supplied to each space separately. Thus, each space is heated separately. Of course, each space is also heated by the heating pipe (12).

At this time, when the temperature of the room becomes too high due to the continuous heating, the temperature control button or the OFF button of the switch or the remote controller is operated. Here, the temperature control button is a button for operating the opening and closing valve (V) of the duct (D). Therefore, when the temperature control button is operated, the on-off valve V slowly opens or closes the passage of the duct D slightly or half-opening while gradually rotating according to the operation state of the temperature control button. Alternatively, the passage of the duct D may be completely opened or closed.

At this time, when the duct (D) is composed of a plurality of ducts (D2), it is preferable that the temperature control button is configured to control the operation of the opening and closing valve (V) respectively installed in the plurality of ducts (D2), respectively. Do. In such a configuration, since the plurality of open / close valves V are controlled individually, the temperatures of the respective rooms to which the plurality of ducts D2 are connected can be controlled individually.

Therefore, the temperature of the room is adjusted as the flow rate of the heat supplied to the duct D is controlled by the on-off valve V. Of course, it is obvious that such on-off valve (V) should be configured to operate automatically. If the on-off valve V is not configured to operate automatically, the user goes to the radiator 20 to manually operate the on-off valve V of the duct D to adjust the flow rate of the duct D. Should be.

Here, when the above-described temperature control button is configured to adjust only the air volume of the blower fan 26, the temperature control button controls the rotational speed of the blower fan 26 to adjust the temperature. In more detail, when operating the temperature control button to lower the temperature of the room, the blowing fan 26 rotates slowly. On the contrary, when the temperature control button is operated to raise the indoor temperature, the blowing fan 26 rotates rapidly. As a result, the flow rate of the heat supplied to the room through the duct D is controlled. Thus, the temperature of the room is controlled. In this way, when the temperature control button is configured to operate, the above-described opening and closing valve (V) may be omitted.

On the other hand, the ringer trap 28 supplies the water droplets every 30 seconds to the through hole 22c formed in the case 22 or the duct D through the nozzle N below. Thus, the water droplets supplied are supplied to the duct D together with the heat while evaporating by the heat blown by the blowing fan 26. Therefore, the heat containing moisture is supplied to the room. That is, the ringer trap 28 serves as a humidifier.

As such, when the heating is completed by the heating pipe 12 and the radiator 20, the operation of the boiler 10 and the radiator 20 is terminated by operating an OFF button of a switch or a remote controller. Of course, in some cases, only the operation of the radiator 20 can be terminated.

On the other hand, FIG. 3 is a state diagram in which the heater shown in FIG. 1 is applied to the vinyl house, and illustrates a heating of the vinyl house (VH) adjacent to the building and the interior of the building using the heater of the present invention.

As shown, the boiler 10 is installed in the building, the duct (D) connected to the radiator 20 is installed in the interior of the plastic house (VH). At this time, the heating pipe 12 connected to the boiler 10 is embedded in the interior of the building. Then, the duct (D) is fixed to the frame (FR) of the vinyl house (VH) using the U bolt (U), as shown enlarged. This, U bolt (U) is preferably formed to form a hook on the top as shown. When the hook is formed on the upper end of the U bolt (U) in this way, by hooking the hook to the frame (FR) can be fixed to the duct (D) in the plastic house (VH).

On the other hand, the lower portion of the duct (D) is preferably formed with a plurality of discharge holes at equal intervals as shown in the enlarged heat discharge. Therefore, heat is supplied to the inside of the vinyl house VH through this discharge hole.

On the other hand, the heater according to the present invention can be installed inside the vinyl house (VH), unlike shown. In this case, the boiler 10 and the radiator 20 are naturally arranged inside the vinyl house VH. In this case, the heating pipe 12 may be embedded in the ground of the vinyl house (VH), or disposed on the ground.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and the scope of application of the present invention is not limited thereto, and may be appropriately changed within the scope of the same idea. Therefore, the shape and structure of each component shown in the embodiment of the present invention can be carried out by modifying, it is natural that such modifications belong to the utility model registration claims of the present invention attached.

The heater and the combined heater according to the present invention as described above, since the heating pipe heats the building structure of the room and the radiator heats the air of the room, there is an effect that can be heated three-dimensionally in the room in a short time.

In addition, since the radiator acts as a hot air blower to blow the warm air by using the heat fluid heated in the boiler, you do not have to purchase a hot air heater separately from the boiler, and because the radiator uses the heat fluid heated in the boiler, a separate fuel There is also an economic effect that does not require the use of.

1 is a plan view showing the configuration of a heater and a combined heater according to the embodiment of the present invention,

2 is a plan view showing the configuration of the radiator shown in FIG.

Figure 3 is a state of use of applying the heater shown in Figure 1 in a plastic house.

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

10: boiler 12: heating piping

20: radiator 22: case

24: bypass tube 24a: heat dissipation fins

26: blower fan 28: ringer trap

D: Duct F: Filter

V: On-off valve

Claims (4)

In the radiator for heating the interior of the building, A boiler 10 for heating and supplying a liquid thermal fluid to a high temperature; One end and the other end is connected to the boiler 10, embedded in the floor or wall of the room, the heating pipe 12 of the closed loop type to heat the room while circulating the heated thermal fluid of the boiler 10 and ; Radiator 20 for supplying the heat of the heat fluid heated in the boiler (10) to the room; characterized in that it comprises a hot air heater and a boiler combined heater. The method of claim 1, The radiator 20, A tubular case (22) having air inlets (22a) and air outlets (22b) on one side and the other side, and having a hollow; The bypass pipe of the closed loop type which is disposed in the hollow of the case 22, bypasses a part of the heated heat medium supplied from the boiler 10 to the heating pipe 12, and circulates it while sending it back to the boiler 10. (24) and; A blowing fan 26 which blows air to the bypass pipe 24 and discharges the heat of the bypass pipe 24 heated by the heated heating medium to the air outlet 22b of the case 22; Heater and boiler combined heater, characterized in that it comprises. The method of claim 2, At least one duct (D) integrally connected to the air outlet (22b) of the case 22 to direct the heat discharged from the air outlet (22b) to a predetermined position in the room; Heaters and boilers. The method of claim 2, A heat dissipation fin (24a) integrally mounted to the bypass tube (24) to dissipate the heated heat of the bypass tube (24); A filter (F) installed at at least one of the air inlet (22a) and the air outlet (22b) of the case 22 to filter impurities in the air flowing into or out of the case (22); Heater and boiler combined heater characterized in that.