JP2005098544A - Portable heater for outdoor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable heater for outdoor capable of preventing blown-out of flames by wind, improved in radiation efficiency, and reduced in cost. <P>SOLUTION: A plate-like porous ceramic burner 6 having a plurality of holes 6a for injecting LP gas to be supplied from a LP gas cylinder is provided in a front side of a box 2 for removably housing the LP gas cylinder, and a guard 7 is provided in a front side of the porous ceramic burner 6. In the portable heater for outdoor with this structure, a mesh panel 8 having a metal net 8a of 45-60 mesh is interposed between the porous ceramic burner 6 and the guard 7 to cover the front surface of the porous ceramic burner 6 to relax direct influence of the wind blown out of the plurality of holes 6a in relation to the flames. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an outdoor portable heater, and more specifically, an outdoor portable heater that prevents a flame from being blown out by wind, increases radiation efficiency, and enables reduction in fuel consumption. It relates to a heater.

  As the portable heater, for example, one having a configuration described later is known. The portable heater according to the conventional example 1 is a portable warm air heater, which protects a controller equipped with electronic components from a temperature rise and an unexpected impact force, and makes the appliance compact. It is a thing. More specifically, the blower is provided in a state where the bottom wall surface of the combustion chamber is airtight in accordance with the width of the combustion chamber. As a result, the combustion of the burner mixes the soot and the room air, and blows out the mixed warm air from the louver so as to have a long reach distance in front of the installation floor. Also, with this configuration, a space between the bottom of the blower and the bottom of the main body, which is inevitably generated, is effectively used, and a controller in which a transistor and an IC element are mounted is accommodated (for example, see Patent Document 1). ).

In recent years, the trend of enjoying outdoors has increased, and it is no exception in early winter, winter and early spring. In the early winter, winter and early spring, it is naturally cold, so heating equipment is indispensable outdoors. By the way, the portable warm air heater according to the above-mentioned conventional example 1 is for indoor use and is configured to use household gas, so it cannot be used outdoors.
For this reason, portable heaters using an LP gas cylinder as a fuel source for portable gas stoves are used outdoors. As such a portable heater, there exists what becomes the structure mentioned later, for example.

  That is, the portable heater according to Conventional Example 2 includes a box that detachably stores an LP gas cylinder, and a plurality of pores that eject LP gas supplied from the LP gas cylinder on the front side of the box. A plate-like porous ceramic burner is provided. And the guard is provided in the front side of the said porous ceramic burner (for example, refer patent document 2).

JP-A-7-280351 Registered Utility Model Publication No. 3060355 (FIG. 1)

  Since the portable heater according to Conventional Example 2 can be used outdoors because of the LP gas cylinder as a fuel source, it is considered to be extremely useful for recreation in early winter, winter, and early spring. However, the portable heater according to Conventional Example 2 has a problem that the flame blown out from the plurality of pores of the porous ceramic burner is blown out by the wind and cannot be used in a strong wind. Of course, if the amount of LP gas supplied is increased to make the flame stronger, it can withstand strong winds. However, the usable time of one LP gas cylinder is shortened, which is not preferable. In other words, it has been desired to realize a portable heater that does not blow out a flame even in a strong wind, consumes less LP gas, and can take a predetermined warm for a long time.

  Accordingly, an object of the present invention is to provide a portable outdoor heater that prevents the flame from being blown out by the wind and enables the consumption of fuel to be reduced.

  The present invention has been made in view of the above circumstances, and therefore, in order to solve the above-described problems, the configuration adopted by the outdoor portable heater according to claim 1 of the present invention is an detachable LP gas cylinder. A plate-like porous ceramic burner (6) having a plurality of pores (6a) for ejecting LP gas supplied from the LP gas cylinder is provided on the front side of the freely storing box (2). A ceramic burner (6) is provided with a pilot burner (10) for igniting LP gas blown from a plurality of pores (6a), and a guard (7) is provided on the front side of the porous ceramic burner (6). In the portable heater for the above, a flame that covers the front surface of the porous ceramic burner (6) between the porous ceramic burner (6) and the guard (7) and blows out from the plurality of pores (6a) (9) It features a mesh panel (8) that mitigates the direct influence of the wind on it.

  The configuration adopted by the outdoor portable heater according to claim 2 of the present invention is the outdoor portable heater according to claim 1, wherein the mesh panel (8) has a wire mesh of 30-60 mesh. (8a) is provided.

  The configuration adopted by the outdoor portable heater according to claim 3 of the present invention is the outdoor portable heater according to any one of claims 1 and 2, wherein the mesh panel ( The distance between the back surface of the wire mesh (8a) of 8) and the surface of the porous ceramic burner (6) is set to 3 to 17 mm.

  The configuration adopted by the outdoor portable heater according to claim 4 of the present invention is the outdoor portable heater according to any one of claims 1 to 3, wherein the mesh panel ( A feature of 8) is that a pilot burner cover (8c) for preventing the fire of the pilot burner (10) from being blown out by wind is provided.

  According to the portable heater according to claims 1 to 4 of the present invention, since the wind is blocked by the metal mesh of the mesh panel, there is a possibility that the flame blown out from the plurality of pores of the porous ceramic burner is blown out by the wind. Less. And even if the flame blown out from the plurality of pores of the porous ceramic burner is blown out by the wind, heat is generated between the porous ceramic burner and the mesh panel, and the mesh panel is red hot by this rising heat. Therefore, the LP gas blown out from the plurality of pores of the porous ceramic burner is ignited and recombusted.

  Moreover, in the portable heater which concerns on the prior art example 2, since the air heated with the flame escaped upwards, there was little contribution with respect to the heating of the front direction. However, in the case of the portable heater according to the first to fourth aspects of the present invention, the porous ceramic burner whose temperature rises due to heat generated between the porous ceramic burner and the mesh panel, and the mesh panel which is red hot The heating performance in the forward direction of the portable heater is improved by the heat rays radiated from the two locations. Therefore, according to the portable heater according to claims 1 to 4 of the present invention, the amount of LP gas consumed per unit time to obtain the same heating effect as that of the portable heater according to Conventional Example 2 is reduced. can do.

According to the portable heater according to claim 4 of the present invention, since the wind is blocked by the pilot burner cover, there is no possibility that the pilot burner will be blown out.
Therefore, even if the flame blown out from the plurality of pores of the porous ceramic burner is blown out by the wind, the LP gas blown out from the plurality of pores (6a) is ignited by the pilot burner fire. The

  Hereinafter, a portable heater according to an embodiment of the present invention will be described with reference to the attached drawings. FIG. 1 is a front view of a portable heater according to an embodiment of the present invention, FIG. 2 is a longitudinal side view schematically showing a main part of the portable heater according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention. It is a front view of the mesh panel of the portable heater which concerns.

First, a portable heater according to an embodiment of the present invention will be described with reference to FIGS.
The code | symbol 1 shown in FIG. 1 is the portable heater which concerns on the form of this invention. The portable heater 1 includes a box 2 for detachably storing an LP gas cylinder (not shown), and has a handle 4 provided on the top of the box 2 so that the portable heater 1 can be easily carried. Has been. A flat porous ceramic burner 6 having a plurality of pores 6a for blowing out LP gas supplied from an LP gas cylinder is provided on the front surface of the box 2. The LP gas blown out from the plurality of pores 6 a of the porous ceramic burner 6 is configured to be ignited by a pilot burner 10 provided below the porous ceramic burner 6. A guard 7 is provided on the front side of the box 2 and on the front side of the porous ceramic burner 6. A mesh panel that covers the front surface of the porous ceramic burner 6 inside the guard 7 and reduces the direct influence of wind on the flame 9 blown out from the plurality of pores 6a of the porous ceramic burner 6 (blocks the wind). 8 is provided.

  As shown in FIG. 3, the mesh panel 8 includes a 40 mesh wire mesh 8a made of nickel chrome steel wire, and the outer edge of the wire mesh 8a is held by a frame body 8b made of rectangular stainless steel. A pilot burner cover 8c that protrudes downward and covers the pilot burner 10 to prevent the fire of the pilot burner 10 from being blown off by wind is provided at the center position in the width direction of the frame 8b. ing. Since the wind can be blocked by covering the pilot burner 10 with the pilot burner cover 8c, the fire of the pilot burner 10 is prevented from being blown out by the wind. Therefore, even if the flame blown out from the plurality of pores of the porous ceramic burner is blown off by the wind, the LP gas blown out from the plurality of pores 6a is ignited and burned by the fire of the pilot burner 10 to the porous ceramic burner 6. It will be. Moreover, there is also a design effect that the appearance of the portable heater 1 is improved by making the red fire of the pilot burner 10 invisible.

  In addition, although the metal mesh 8a of the mesh panel 8 is set to 40 mesh as described above, the metal mesh 8a is preferably set to 30 to 60 mesh, more preferably 35 to 55 mesh. That is, if the wire mesh 8a is less than 30 mesh, the flame 9 may be blown off in strong winds. Conversely, if the wire mesh 8a exceeds 60 mesh, the space between the porous ceramic burner 6 and the mesh panel 8 may be reduced. This is because there is a problem with the danger of explosion of the LP gas cylinder due to the temperature rise of the portable heater 1 due to excessive heat, and a decrease in the durable life of the mesh panel 8 due to the wire diameter of the wire mesh 8a becoming narrow. In this embodiment, the interval between the surface of the porous ceramic burner 6 and the back surface of the wire mesh 8a is set to 10 mm, but this interval is set to 3 to 17 mm, more preferably 5 to 15 mm. It is preferable to do this. A heater adjustment knob 3 for adjusting the ignition, digestion, and supply amount of LP gas is provided at the center upper portion of the box 2 in the width direction and inside the handle 4. Further, a leg 5 for supporting the box 2 is attached to the lower part of the box 2.

  Hereinafter, the operation mode of the portable heater 1 according to the embodiment of the present invention will be described. That is, when the heater operation knob 3 is operated, LP gas is supplied from the LP gas cylinder to the porous ceramic burner 6. The LP gas blown out from the pores 6a of the porous ceramic burner 6 is ignited by the pilot burner 10 and burned. As a result, the function as a heater is exhibited. However, according to the portable heater 1 according to the embodiment of the present invention, the wind is blocked by the metal mesh 8a of the mesh panel 8, so that a plurality of pores of the porous ceramic burner 6 are provided. There is less possibility that the flame 9 blowing out from 6a is blown out by the wind. Even if the flame 9 blown out from the plurality of pores 6a of the porous ceramic burner 6 is blown off by the wind, the mesh panel 8 is red hot by the heat that flows between the porous ceramic burner 6 and the mesh panel 8. Further, since the wind is not blocked by the pilot burner cover 8c and the fire of the pilot burner 10 is not blown out, the LP gas blown out from the plurality of pores 6a of the porous ceramic burner 6 is surely ignited. It will burn again.

  Further, in the case of the portable heater according to Conventional Example 2, since the air heated by the flame escapes upward due to convection, the portable heater contributes little to the forward heating. However, in the portable heater 1 according to the embodiment of the present invention, as described above, the porous ceramic burner 6 whose temperature rises due to heat generated between the porous ceramic burner 6 and the mesh panel 8, and the mesh that is red hot. The heating performance in the forward direction of the portable heater 1 is improved by the heat rays radiated from two places with the panel 8. Therefore, according to the portable heater 1 according to the embodiment of the present invention, it is possible to reduce the amount of LP gas consumed per unit time to obtain the same heating effect as the portable heater according to the conventional example 2. it can.

  Hereinafter, an example of a portable heater according to an embodiment of the present invention will be described with reference to the accompanying drawings. FIG. 4 is an explanatory diagram of the ambient temperature of a portable heater (hereinafter referred to as a comparative example) when no mesh panel is attached, and FIG. 5 is a portable heater according to an embodiment of the present invention (hereinafter referred to as this example). Ambient temperature explanatory diagram, FIG. 6 shows temperature (° C.) on the vertical axis and time (minutes) on the horizontal axis, the case of this example is indicated by a black triangle mark and a solid line, and the case of the comparative example is indicated by a black square mark. The box backside temperature explanatory graph shown by the solid line is shown respectively.

First, in order to confirm the difference in the heating effect between the comparative example and the present example, the temperature at a later-described position of the portable heater was measured using a chromel-alumel thermocouple. In the case of the comparative example, as shown in FIG. 4, the temperature at the position A at the center of the upper end of the porous ceramic burner 6, 15 mm just 20 mm ahead of the front surface of the box 2, and the porous ceramic burner 6 The temperature at position B on the central surface was measured. In the case of this example, as shown in FIG. 5, the temperature at the position C at the center of the upper end of the porous ceramic burner 6 and 15 mm just 20 mm ahead of the front surface of the box 2 (the position A in the comparative example). ), The temperature at the position D on the center surface of the porous ceramic burner 6 (corresponding to the temperature at the position B in the comparative example), and the temperature at the position E on the center surface of the mesh panel 8 were measured. . The results are as shown below.
Comparative example: temperature at position A; 617 ° C., temperature at position B; 724 ° C.
Example: Temperature at position C; 460 ° C., temperature at position D; 838 ° C., temperature at position E; 693 ° C.

  According to the result of the temperature measurement, the temperature at the position C in this example is 157 ° C. lower than the temperature at the position A in the comparative example, and the temperature at the position D in this example is 114 degrees lower than the temperature at the position B in the comparative example. ℃ higher. In other words, in the case of this example, the radiation is radiated from two places, that is, the porous ceramic burner 6 whose temperature is increased by the heat generated between the porous ceramic burner 6 and the mesh panel 8 and the mesh panel 8 that is red hot. It is suggested that the heating performance in the forward direction of the portable heater 1 is improved by the hot wire. Therefore, according to this example, it can be said that it is possible to reduce the amount of LP gas consumed per unit time to obtain the heating effect equivalent to that of the comparative example. The consumption of LP gas in this temperature measurement was 44.6 gf in 30 minutes.

  For this reason, the amount of heat generated per 5 minutes was adjusted to 3.767-4.164 MJ (900-1000 kcal) by adjusting the supply amount of LP gas, and the heat generation per 5 minutes was 6.070 MJ (1450 kcal). When the sensory temperature comparison with the comparative example made was performed, the warmth of this example and the comparative example was equivalent. This suggests that LP gas consumption can be reduced. These calorific values are all calculated from the consumption of LP gas per 5 minutes.

In addition, in order to confirm the difference due to the difference in the distance between the surface of the porous ceramic burner 6 and the back surface of the wire mesh 8a, and to obtain the most excellent distance, the mesh panel having a distance of 5 mm, 10 mm, or 15 mm is porous. A radiation efficiency test was performed for the case where the surface of the ceramic burner 6 was covered and the case where the surface was not covered. In this radiation efficiency test, a test apparatus having a semicircular arc-shaped curved frame having a radius of 1 m that can be rotated in eight stages with an axis perpendicular to the center of the string as a rotation center was used. Then, while moving the radiation intensity measuring sensor to a plurality of locations on the curved frame and rotating the curved frame, the radiation strength Ei at 33 locations on the hemisphere 1 m away from the center of the surface of the porous ceramic burner 6 is obtained. (KW / m ² ) was measured respectively. Next, based on the measured radiation intensity Ei (kW / m ² ) and the calorific value I (kW) calculated from the LP gas consumption, the radiation efficiency η (%) is calculated as follows: η = (2πr ² ΣEi / 33I) It was determined by a calculation formula of x100 (r is the radius of the curved frame is 1 m). The results are as follows when the surface temperature of the mesh panel (denoted as panel surface temperature) ° C. and the surface temperature of the porous ceramic burner (denoted as burner surface temperature) ° C. are shown together. This radiation efficiency test was conducted by a public organization in Komaki City, Aichi Prefecture.

a. When the distance between the surface of the porous ceramic burner 6 and the wire mesh 8a is 5 mm Radiation efficiency: 49.4%, panel surface temperature; 824 ° C, burner surface temperature; 964 ° C
b. When the distance between the surface of the porous ceramic burner 6 and the wire mesh 8a is 10 mm Radiation efficiency: 50.3%, panel surface temperature: 742 ° C., burner surface temperature: 1017 ° C.
c. When the distance between the surface of the porous ceramic burner 6 and the wire mesh 8a is 15 mm Radiation efficiency: 48.4%, panel surface temperature: 630 ° C., burner surface temperature: 1000 ° C.
d. Radiation efficiency without porous ceramic burner: 34.0%, burner surface temperature: 790 ° C

  From the above test results, the heating performance of the portable heater is most excellent when the distance between the porous ceramic burner 6 and the back surface of the mesh panel 8 is 10 mm. However, when the porous ceramic burner 6 is covered with the mesh panel 8, the radiation efficiency is greatly improved as compared with the case where the porous ceramic burner 6 is not covered, and it is understood that both are effective for improving the heating performance. . Incidentally, the radiation efficiency of a commercial household gas stove is 20-30%, and the radiation efficiency of a radiant electric stove is about 34.8%. By the way, in the temperature measurement result for confirming the difference in the heating effect described in paragraph [0021], the temperature at the position D as the burner surface temperature is 838 ° C., and the temperature at the position E as the panel surface temperature is 693. It is a degree of C and is quite different from the data of the above-mentioned item b measured in this radiation efficiency test. Such a difference can be attributed to a difference in test conditions. Although not specifically shown in this radiation efficiency test, it has been confirmed that the radiation efficiency is improved even with a mesh panel having a 30-mesh wire mesh.

  The present invention relates to a portable heater for outdoor use. However, since the heating performance can be improved and the fuel consumption can be reduced, the technical idea of the present invention can also be applied to a household gas heater.

It is a front view of the portable heater which concerns on the form of this invention. It is side surface sectional drawing which shows typically the principal part of the portable heater which concerns on the form of this invention. It is a front view of the mesh panel of the portable heater which concerns on the form of this invention. It is explanatory drawing of the ambient temperature of the portable heater when not installing a mesh panel. It is ambient temperature explanatory drawing of the portable heater which concerns on the form of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Portable heater 2 ... Box 3 ... Heater operation knob 4 ... Handle 5 ... Base 6 ... Porous ceramic burner, 6a ... Pore 7 ... Guard 8 ... Mesh panel, 8a ... Wire mesh, 8b ... Frame, 8c ... Pilot burner cover 9 ... Flame 10 ... Pilot burner

Claims (4)

  A flat porous ceramic burner (6) having a plurality of pores (6a) for ejecting LP gas supplied from the LP gas cylinder is provided on the front side of the box (2) for detachably storing the LP gas cylinder. The porous ceramic burner (6) is provided with a pilot burner (10) for igniting LP gas blown from a plurality of pores (6a), and a guard (7) is provided on the front side of the porous ceramic burner (6). In the outdoor portable heater, the front surface of the porous ceramic burner (6) is covered between the porous ceramic burner (6) and the guard (7), and the plurality of pores (6a ) A portable heater for outdoor use, which is equipped with a mesh panel (8) that mitigates the direct influence of the wind on the flame (9) that blows out.   The portable heater for outdoor use according to claim 1, wherein the mesh panel (8) comprises a wire mesh (8a) of 30 to 60 mesh.   The distance between the back surface of the metal mesh (8a) of the mesh panel (8) and the surface of the porous ceramic burner (6) is set to 3 to 17 mm. A portable heater for outdoor use according to any one item.   The pilot burner cover (8c) for preventing the fire of the pilot burner (10) from being blown out by wind is provided on the mesh panel (8). A portable heater for outdoor use according to one item.