KR20030021042A - Gas combustion apparatus for dryer - Google Patents

Abstract

PURPOSE: An apparatus for gas combustion for a drier is provided to increase heat efficiency. CONSTITUTION: An apparatus includes a heating part supplying heat for generation of hot blast; a heat insulating duct having air flowing therein, and supplying hot blast generated in the heating part to a drying chamber; and a hot blast duct(50) coaxially installed in the heat insulating duct, having a mixing hole(54), and generating hot blast by heat generated in the heating part to flow to the heat insulating duct. The mixing hole transmits air flowing through the heat insulating duct to an inside of the hot blast duct and has a guide piece to guide air in the heat insulating duct.

Description

Gas combustion apparatus for dryer

The present invention relates to a dryer, and more particularly, to a hot air supply for a dryer for providing hot air to the interior of the drum is drying.

1 is an exploded perspective view showing a main configuration of a dryer according to the prior art. According to this, the drum 1 is installed inside a cabinet (not shown) constituting the exterior of the dryer. The drum 1 is formed in a cylindrical shape with both ends open, and a belt groove 2 around which a belt (not shown) driven by a separate driving source is wound is formed along the middle of the outer circumferential surface thereof. The drying chamber 5 in which drying proceeds is formed in the drum 1. A plurality of baffles 6 are formed inside the drying chamber 5 to turn over the object to be dried in the drying chamber 5 when the drum 1 rotates.

The front head 7 and the rear head 9 are installed to correspond to the front and rear ends of the drum 1, respectively. Here, the front head 7 and the rear head 9 form a drying chamber 5 by blocking the open portion of the drum 1 and serve to support the front and rear ends of the drum 1, respectively. In this case, a sealing member 10 is installed between the front head 7 and the drum 1 which are relatively rotated, and between the rear head 9 and the drum 1 to prevent leakage. Of course, a plurality of rollers (not shown) for supporting the drum 1 are installed at positions corresponding to the front and rear ends of the drum 1.

The front head 7 is formed with a through hole 8 for communicating the interior and exterior of the drying chamber (5). The through hole 8 is selectively opened and closed by a door (not shown).

An air supply duct 12 is installed in the rear head 9, and the air supply duct 12 serves as a passage for supplying air, more precisely, hot air, into the drying chamber 5. It communicates with the interior of the drying chamber 5.

And one side of the front head 7 corresponding to the lower end of the through hole 8 of the front head 7 is provided with an outlet assembly 13 which is a part from which air escapes from the drying chamber 5. The outlet assembly 13 is provided with a lint filter 14. The lint filter 14 serves to filter foreign matter (for example, seams or dust) mixed in the air flowing out of the drying chamber 5.

The lint duct 15 is installed in communication with the outlet assembly 13, and the lint filter 14 is positioned to the inside of the lint duct 15. The blower 17 is installed to be connected to the lint duct 15 to suck the air inside the drying chamber 5 through the lint duct 15. The blower 17 is installed inside the blower housing 18. One side of the blower housing 18 communicates with the lint duct 15, and an exhaust pipe 19 is connected to the other side. Therefore, the air exiting the drying chamber 5 and passing through the lint duct 15 is discharged to the outside through the exhaust pipe 19 by the force of the blower 17.

On the other hand, the hot air duct 20 is installed to be connected to the air supply duct (12). The hot air duct 20 serves to supply hot air having a drying function in the drying chamber 5. To this end, the hot air duct 20 is provided with a configuration for generating heat energy for heating the air.

That is, a gas nozzle 22 is installed at the inlet of the hot air duct 20. The gas nozzle 22 serves to inject the supplied gas. The gas nozzle 22 is provided with a valve for controlling the supply of gas. Reference numeral 23 is a gas pipe.

A mixing tube 24 for mixing the gas injected from the gas nozzle 22 and the primary air is installed to extend from the inlet of the hot air duct 20 to the inside. Here, the inlet of the mixing tube 24 is located to correspond to the gas nozzle 22. Inside the mixing tube 24, the gas injected from the gas nozzle 22 and the external air introduced through the inlet of the mixing tube 24, that is, primary air, are mixed. The spark plug 26 is installed at the tip of the mixing tube 24 to generate spark for ignition.

It will be described that the dryer according to the prior art having such a configuration is operated.

After putting the laundry cloth to be dried into the drying chamber 5 formed in the drum 1 and closing the door, pressing the operation button, the belt wound around the belt groove 2 is driven by a separate driving source. The drum 1 is rotated.

Then, the blower 17 is operated to suck the air inside the drying chamber 5 through the lint duct 15. In this case, the outside air flows into the drying chamber 5 through the air supply duct 12.

Here, the air supplied to the air supply duct 12 becomes a relatively high temperature while passing through the hot air duct 20. That is, gas is injected into the mixing tube 24 through the gas nozzle 22, and primary air enters the inlet of the mixing tube 24, and the gas is mixed with the gas in the mixing tube 24. The air is mixed and is first ignited and burned by the spark plug 26 at the outlet of the mixing tube 24.

As such, the heat energy generated by the combustion of the gas heats the air sucked by the suction force driven by the blower 17 into the hot air duct 20 to make hot air.

The hot air is delivered to the interior of the drying chamber 5 formed inside the drum 1 through the air supply duct 12. The hot air in the drying chamber (5) absorbs the moisture contained in the laundry cloth, and then exits from the drying chamber (5) through the outlet assembly (13). At this time, the air is discharged from the drying chamber 5 through the outlet assembly 13 is made by the suction force of the blower (17). Air passing through the outlet assembly 13 is filtered through the lint filter 14 so that foreign matter such as dust or seams is filtered out.

However, the prior art having the above configuration has the following problems.

Heat generated by the combustion of gas in the hot air duct 20 is used to heat the hot air delivered to the air supply duct 12 and is also transmitted to the hot air duct 20 itself. Therefore, heat is transferred to the outside of the hot air duct 20 through the hot air duct 20, so that a large amount of heat loss occurs.

In addition, the heat transferred to the surface of the hot air duct 20 increases the temperature inside the dryer, and in particular, there is a problem in that damage to the heat weak components located near the hot air duct 20 or severe fire occurs.

Therefore, an object of the present invention is to solve the problems of the prior art as described above, to increase the thermal efficiency in the hot air supply device for a dryer.

Another object of the present invention is to prevent the heat generated in the hot air supply device for the dryer does not affect the peripheral parts.

1 is an exploded perspective view showing the main configuration of the dryer according to the prior art.

Figure 2 is a cross-sectional view showing the configuration of a hot air supply device for a dryer according to the prior art.

Figure 3 is a side cross-sectional view showing the configuration of a preferred embodiment of a hot air supply device for a dryer according to the present invention.

Figure 4 is a plan sectional view showing the main portion of the embodiment shown in FIG.

FIG. 5 is a sectional view showing a main part configuration of the embodiment shown in FIG. 3; FIG.

6 is a cross-sectional view showing the main part configuration of another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

30: heating portion 32: gas nozzle

34: mixing tube 36: spark plug

37: base 39: seating group

40: heat insulation duct 42: heat insulation flow path

45: support 50: hot air duct

52: combustion flow path 54: mixing hole

56: Guide

According to a feature of the present invention for achieving the above object, the present invention provides a heat generating unit for providing heat for generating hot air, the air flows through the inside and supplies the hot air generated in the heat generating unit to the drying chamber And a hot air duct installed in the heat insulating duct and hot air ducts formed by heat generated by the heat generating unit to flow into the heat insulating duct.

The hot air duct is installed to be concentric in the heat insulation duct.

The hot air duct is provided with a mixing hole to allow the air flowing through the heat insulating duct to be transferred into the hot air duct, the mixing hole is provided with a guide piece for guiding the air of the heat insulating duct.

The hot air duct is fixedly installed by a connection support inside the heat insulation duct.

The hot air duct is installed to be concentric inside the heat insulation duct, and a plurality of support protrusions protrude toward the center of the heat insulation duct on the inner surface of the heat insulation duct to support the hot air duct.

The hot air supply device for a dryer according to the present invention having such a configuration has an advantage of maximizing its thermal efficiency and preventing the surrounding parts from being damaged by heat.

Hereinafter, preferred embodiments of the hot air supply device for a dryer according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings. The same as those of the prior art will be described using the symbols of the prior art drawings.

3 to 5, the heat generating unit 30 is provided to form hot air supplied into the drying chamber 5. Referring to the configuration of the heat generating unit 30, a gas nozzle 32 for supplying gas is provided on the seating end 39 is installed in the base 37 forming the bottom of the dryer.

In addition, the gas nozzle 32 and its inlet correspond to the mixing pipe 34. The outlet side of the mixing tube 34 extends into the hot air duct 50 to be described below. The mixing pipe 34 is installed to be supported by the seating end 39 as a portion where the gas injected from the gas nozzle 32 and the primary air are mixed. On the outlet side of the mixing tube 34, a spark plug 36 is provided to ignite the gas mixed with the primary air injected from the mixing tube 34.

In the present embodiment, the heat generating unit 30 is configured to obtain heat by combustion of gas, but it is not necessary to do so, for example, an electric heater may be used as the heat generating unit 30.

Next, the portion corresponding to the outlet side of the mixing pipe 34 is provided with a heat insulating duct 40 in communication with the air supply duct 12 for guiding hot air to the drying chamber (5). The insulated duct 40 has its inlet open and its outlet is in communication with the air supply duct 12. The hot air duct 50 to be described below is installed inside the heat insulation duct 40, and the rest of the heat insulation duct 40 forms an heat insulation flow passage 42 through which air sucked from the outside flows. The air flowing through the heat insulating channel 42 serves to prevent the heat transferred from the hot air duct 50 to be described below to be transferred to the outside of the heat insulating duct 40.

On the other hand, the insulated side duct 40 is supported by the support 45 is installed on the base 37, the outlet side is connected to the air supply duct 12 is supported.

The hot air duct 50 is installed inside the heat insulation duct 40. The outlet of the mixing pipe 34 is located in the hot air duct 50, and combustion of gas is performed therein. The combustion passage 52 is formed inside the hot air duct 50, and the air sucked from the outside flows, and receives the heat generated by the combustion of the gas to become the hot air.

A mixing hole 54 is formed at the tip of the hot air duct 50 to communicate the heat insulating path 42 of the heat insulating duct 40 with the combustion flow path 52 of the hot air duct 50 around the outer circumferential surface thereof. Each of the mixing holes 54 is provided with a guide piece 56 for guiding air from the heat insulation passage 42 to the combustion passage 52. The air flowing along the adiabatic flow passage 42 by the mixing hole 54 is transferred to the combustion flow passage 52, mixed with the hot air formed in the combustion flow passage 52, and flows into the air supply duct 12.

The hot air duct 50 is supported by a plurality of connection supports 60 in the heat insulation duct 40. As shown in FIG. 5, the connection support 60 is installed on the outer circumferential surface of the hot air duct 50 by fastening a plurality of screws, and the front end thereof is an inner surface of the heat insulating duct 40. In close contact with the hot air duct 50 is installed concentrically in the heat insulating duct (40).

On the other hand, Figure 6 shows an embodiment in which the hot air duct 50 is installed in a different form inside the heat insulation duct 40. According to this, a plurality of support protrusions 65 protrude toward the center of the heat insulation duct 40 on the inner surface of the heat insulation duct 40. In addition, the outer circumferential surface of the hot air duct 50 is fitted to the support protrusion 65 so that the hot air duct 50 can be installed concentrically on the heat insulation duct 40.

Hereinafter, the operation of the hot air supply device for a dryer according to the present invention having the configuration as described above.

When the dryer is operated, hot air is supplied into the drying chamber 5 while the drum 1 rotates, and drying proceeds. The hot air supplied into the drying chamber 5 absorbs the moisture contained in the laundry cloth and is discharged to the outside by the suction force of the blower 17.

In addition, hot air is supplied through the air supply duct 12 to the inside of the drying chamber 5 by the suction force of the blower 17. At this time, the hot air is formed in the hot air duct 50.

That is, gas is injected into the mixing tube 34 through the gas nozzle 32, and the primary air delivered into the mixing tube 34 is mixed in the mixing tube 34. The gas is ignited and combusted by the spark generated in the spark plug 36 while being discharged from the mixing pipe 34.

By the combustion of the gas, the air flowing through the combustion passage 52 of the hot air duct 50 is heated to be changed to hot air. The air passing through the heat insulation duct 42 of the heat insulation duct 40 receives heat transferred to the surface of the hot air duct 50. As such, the air flowing through the heat insulation passage 42 prevents the heat of the hot air duct 50 from being transferred to the heat insulation duct 40.

That is, by forming the heat insulation passage 42 around the outer circumferential surface of the hot air duct 50 to minimize the loss of heat generated in the heat generating portion 30, to prevent the parts around the hot air supply device from being damaged by heat You can do it.

On the other hand, the mixing hole 54 formed on the downstream side of the hot air duct 50 serves to guide a part of the air passing through the heat insulation passage 42 into the combustion passage 52. In this way, by guiding the air in the heat insulation passage 42 to the combustion flow passage 52, the secondary air can be more smoothly supplied into the combustion flow passage 52, and the air and the heat insulation passage of the combustion flow passage 52 ( The air of 42 may be mixed so that the temperature of the hot air is in an appropriate state, and the air may be delivered to the air supply duct 12.

Dryer hot air supply apparatus according to the present invention as described in detail above to install a heat insulation duct around the hot air duct to form hot air from the heat generated from the heat generating portion and to form a heat insulation flow path between the outer circumferential surface of the hot air duct and the inside of the heat insulation duct It is. By doing so, the heat generated in the heat generating unit is not transmitted to the heat insulating duct by the airflow passing through the heat insulating channel, so that the heat generated in the heat generating unit can be efficiently used without waste.

And since heat is not transmitted to the heat insulation duct, it is possible to prevent the parts around the heat insulation duct from being damaged by heat.

Claims (5)

A heat generation unit for providing heat for generating hot air; Insulation duct for flowing air through the inside and supplying the hot air generated in the heat generating unit to the drying chamber, And a hot air duct installed inside the heat insulation duct and configured to flow into the heat insulation duct by forming hot air by heat generated from the heat generating unit. The hot air supply device for a dryer according to claim 1, wherein the hot air duct is installed to be concentric in the heat insulation duct. According to claim 1 or claim 2, wherein the hot air duct is formed in the mixing hole for the air flowing through the heat insulating duct is transferred to the inside of the hot air duct, the mixing hole is provided with a guide piece for guiding the air of the heat insulating duct Hot air supply device for a dryer, characterized in that. The hot air supply device for a dryer according to claim 1, wherein the hot air duct is fixedly installed in the heat insulating duct by a connecting support. According to claim 1 or 4, wherein the hot air duct is installed to be concentric in the interior of the heat insulation duct, the inner surface of the heat insulation duct to support a plurality of support protrusions toward the center of the heat insulation duct to support the hot air duct. Hot air supply device for a dryer.