Abstract:
A balanced high efficiency outdoor heater is provided to increase the heat radiation area, and to improve the stability of the structure. The heater includes a burner provided at an upper end of a standing column, a bottom base provided at a lower end of the standing column, and a beam is set between the burner and the standing column. The beam and the standing column are connected by pipe fittings. An ignition control device is equipped inside the base and is connected to the burner. An electrode rod and a thermocoupler are connected to the ignition control device under the burner. A first reflector is fixedly connected to the lower end of the burner and a gas valve is equipped in the bottom base. Compared with the prior art, the burner uses sintered felt and a heating surface of the burner faces upside down to improve thermal efficiency.

Description:
NOTICE OF COPYRIGHT 
     A portion of the disclosure of this patent document contains material which is subject to copyright protection. The copyright owner has no objection to any reproduction by anyone of the patent disclosure, as it appears in the United States Patent and Trademark Office patent files or records, but otherwise reserves all copyright rights whatsoever. 
     BACKGROUND OF THE PRESENT INVENTION 
     Field of Invention 
     The present invention relates to a heater. 
     Description of Related Arts 
     Currently, most outdoor heaters use standing columns to prop up burners, for example, patent CN 20052000535 U discloses an infrared remote control heating stove, which uses a standing column to prop up its burner; by arranging a reflecting cover above the burner to reflect the heat; that infrared remote control heating stove has some drawbacks such as low thermal efficiency and small heating space; the heat is circumferentially radiated, resulting in most of the heating area not being utilized; and using a standing column for connecting parts can easily cause the head part of the heater to become askew. 
     SUMMARY OF THE PRESENT INVENTION 
     The main object of the present invention is to provide a balanced high efficiency outdoor heater. The technical problem of the conventional heater to be solved is to increase the heating radiation area and improve the structural stability. 
     To solve the above mentioned problem, the present invention utilizes the following technical improvement: a balanced high efficiency outdoor heater includes a burner, and the burner is set at the upper end of a standing column, and the lower end of the standing column is provided with a bottom base, and the burner is an infrared burner, and a beam is set between the burner and the standing column, wherein the beam and the to standing column are connected by pipe fittings, and the rear end of the beam is provided with a base, and an ignition control device is equipped inside the base, and the burner is mounted on the front end of the beam, and the heating surface of the burner is facing downwards, and an electrode rod and a thermocoupler are connected to the ignition control device under the burner; a first reflector is fixedly connected to the lower end of the burner, and a gas valve is equipped in the bottom base, wherein an inlet and an outlet of the ignition control unit are connected to the burner by a gas pipe in the beam and a gas valve in the bottom base separately. 
     The present invention comprises a burner which further comprises a furnace cover with an opening facing downwards and a combustion chamber, and a furnace cover bracket is set on the upper end of the furnace cover being fixedly connected to the beam; an ejector pipe is transversely arranged inside the combustion chamber, and the ejector pipe is connected to the outlet of the ignition control device by gas pipes; a spoiler is upwardly bent arranged at the front end of the ejector pipe; the first reflector is arranged at the lower end of the furnace cover, and a sintered mat is fixedly set between the furnace cover and the first reflector which can cover the opening of the furnace cover. 
     The ignition control device of the present invention is a gas stove ignition switch, and the ignition switch shaft of the gas stove ignition switch extends from the rear end of the base, and a rotary knob is set on the ignition switch shaft. 
     The ignition control device of the present invention comprises an automatic gas control, a solenoid valve, a battery box, a valve dead plate, and an anti-dumping switch, and the automatic gas control, the solenoid valve, the battery box, and the anti-dumping switch are mounted on the valve dead plate by screws respectively, and the automatic gas control is connected to the battery box, the solenoid valve and the thermocouple respectively, and a first ejector pipe is connected to an outlet of the solenoid valve by gas pipes, and an inlet of the solenoid valve is connected to the gas valve; a key-press pad is fixedly connected to the rear end of the base, and the key-press pad is connected to a control wire end of the automatic gas control, and the key-press pad is provided a faceplate which is bonded to the key-press pad. 
     A second reflector is arranged between the sintered mat and the first reflector, and the reflector surface of the second reflector is smaller than the reflector surface of the first reflector; the second reflector, the first reflector and the sintered mat are fixedly connected to the furnace cover by screws successively. 
     The second reflector further comprises a gas-collecting hood which has a cavity inside; the upper end of the gas-collecting hood extends from the upper end of the second reflector, and the electrode and the thermocouple are arranged inside the cavity of the gas-collecting hood, and louvers are arranged on the lower end surface of the gas-collecting hood for wind shutter purposes. 
     The lower end of the second reflector is connected to a meshed shield cover. 
     Each of the pipe fittings are Tee pipe fittings. 
     The upper end of the burner is provided with a rain cover. 
     The present invention, compared with prior art, utilizes an infrared burner with a sintered mat, and the heating surface of the infrared burner faces downwards, in that case, the thermal efficiency is increased without an open flame; by utilizing the beam to increase the heating area, the whole heating area can be utilized; and the standing column is connected to the beam by pipe fittings, using such a balanced arrangement which can improve the structural stability. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a structure schematic view of the present invention. 
         FIG. 2  is a perspective view illustrating the structure of a burner of the present invention. 
         FIG. 3  is a first structure schematic view of a base of the present invention. 
         FIG. 4  is a second structure schematic view of a base of the present invention. 
         FIG. 5  is a schematic view illustrating the connecting part between the beam and the standing column. 
         FIG. 6  is a structure schematic view illustrating a first preferred embodiment of the ignition control device of the present invention. 
         FIG. 7  is a structure schematic view illustrating a second preferred embodiment of the ignition control device of the present invention. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The following description is disclosed to enable any person skilled in the art to make and use the present invention. Preferred embodiments are provided in the following description only as examples and modifications will be apparent to those skilled in the art. The general principles defined in the following description would be applied to other embodiments, alternatives, modifications, equivalents, and applications without departing from the spirit and scope of the present invention. 
     Referring to  FIG. 1  of the drawings, a balanced high efficiency outdoor heater comprises a bottom base  3 , and a standing column  2  is connected to the bottom base  3 , and a curved beam  4  is connected to the upper end of the standing column  2  by pipe fittings, and a furnace cover bracket  13  is arranged at the front end of the beam  4  connecting by screws, and an ignition control device  6  is connected to the rear end of the beam  4 ; a burner  1  is mounted at the lower end of the furnace bracket  13  with the heating surface facing downwards, and the burner  1  is an infrared burner; the standing column  2  and the beam  4  both have a hollow tube structure, and two gas pipes are arranged inside the standing column  2  and the beam  4 , wherein one gas pipe is connecting the burner  1  and an outlet of the ignition control device  6 , and the another gas pipe is connected to a gas valve  10  and an inlet of the ignition control device  6 , and on the upper end of the burner  1  is provided a rain cover  48 . 
     The beam  4  has a two-section structure, which is a first beam  27  and a second beam  28  with the same outer diameters, and the length of the second beam  28  is less than the length of the first beam  27 . The pipe fitting  5  is a tee pipe fitting. By connecting the pipe fitting  5  with the first beam  27 , the second beam  28  and the standing column  2  by bolts, the interior of the first beam  27 , the second beam  28  and the standing column  2  can communicate with each other, so that the gas pipes can be arranged therein. 
     A base  15  is set at the rear end of the second beam  28 , and the base  15  is provided with a base cover  43  which can be opened, and the gas ignition device  6  is fixed in the base  15 , and the burner  1  is connected to the front end of the first beam  27 . 
     Referring to  FIG. 2 , the burner  1  comprises a furnace cover  12  which is a cuboid, wherein the furnace cover  12  has an opening at the lower end, and the furnace cover  12  comprises a combustion chamber  11 , and the upper end of the furnace cover  12  is connected to a furnace cover bracket  13  by screws; a furnace cover hole  29  is set on the rear end of the furnace cover  12 , and an outer edge  30  is set on the opening of the furnace  12  for connecting other parts like a sintered mat which is extended outwardly, and an ejector pipe  14  is transversely mounted inside of the combustion chamber  11 , and the rear end of the ejector pipe  14  is extended through the furnace cover hole  29  to the outside of the furnace cover  12 , and the rear end of the ejector pipe  14  is hermetically connected to an outlet of the ignition control device  6  by gas pipes; a spoiler  23  being bent upwardly is fixedly connected to the lower end of the pipe orifice at the front end of the ejector pipe  14 , and some small holes are evenly distributed on the spoiler  23 ; the upwardly bent part of the spoiler  23  blocks the front pipe orifice of the ejector pipe  14 , so that exhaust gas from the ejector pipe  14  is guided to the upper end of the inner wall of the furnace cover  12  and be reflected to the front inner wall of the furnace cover  12 , and the gas is exhausted downward; beneath the combustion chamber  11  is provided with an electrode  7  and a thermocouple  22 , and at the lower end opening of the furnace cover  12  is provided with a sintered mat  8  which can completely cover the opening, and the gas is finally discharged to the upper end surface of the sintered mat  8  and burned there, and at the lower end of the sintered mat  8  is successively equipped a first reflector  9  and a second reflector  52  by screws, and the first reflector  9  is in a flared shape, and the shape and the size of the upper end opening of the first reflector  9  is adapted with that of the sintered mat  8 , and the opening diameter of the upper end opening of the first reflector  9  is smaller than the opening diameter of the lower end opening; and the reflect surface of the second reflector  52  is smaller than that of the first reflector  9 , and the second reflector  52  is also in a flared shape, and the shape and the size of the upper end opening of the second reflector  52  is adapted with that of the sintered mat  8 , and the lower end opening diameter is larger than that of the upper end opening; at the rear side of the upper opening of the second reflector  52  is equipped with a gas-collecting hood  24 , and a cavity is set inside the gas-collecting hood  24 , and after the gas-collecting hood being mounted in the second reflector  52 , the upper end of the gas-collecting hood  24  is extended through the upper end opening of the second reflector  52 , and on the lower end surface of the gas-collecting hood  24  is provided with some gas-collecting hood holes  25 . 
     A shield cover  26  is mounted at the lower end of the second reflector  52 , wherein the shield cover  26  is a strip meshed cover, and the shield cover can be connected to the second reflector  52  by screws, and can also be connected to the second reflector  52  by providing some holes on the second reflector  52 , and by using some column which can fit with the holes to fix the shield cover  26 . 
     Furthermore, the thermocouple  22  and the electrode  7  are arranged inside the cavity of the gas-collecting hood  24 . The electrode  7  and the thermocouple  22  are connected by screws on the dead plate of the second reflector  52 . 
     Furthermore, the ejector pipe  14  can be set into two sections, which is a first ejector pipe  31  and a second ejector pipe  32 , and the first ejector pipe  31  is connected by screws to the rear end of the furnace cover hole  29  and outside of the furnace cover  12 , and the front end of the first ejector pipe  31  is plugged into the furnace cover hole  29 , and the second ejector pipe  32  is muff-coupled to the front end of the first ejector pipe  31 , and the second ejector pipe  32  is thread connected to the first ejector pipe  31 ; the second ejector pipe is set inside the combustion chamber  11 , and the spoiler  23  is mounted at the front end orifice of the second ejector pipe  32 ; at the connection part of the first ejector pipe  31  and the second ejector pipe  32  is provided with a gasket  33 , when the ejector pipe is set into two sections, the outlet of the ignition control device  6  is connected to the first ejector pipe  31  by gas pipes, and the first ejector pipe  31  is connected to the gas pipes by thread connection. 
     Referring to  FIG. 3  and  FIG. 4 , the bottom base  3  has an internal hollow barrel structure, which comprises an upper and a lower circular surface referred to as a bottom surface  39  and a top surface  40  respectively, two pieces of semi-circular cross-sectional shaped shells  38  and a framework  46 , and the two shells  38  are hinged on one side, and the other side of the two shells  38  are connected by a snap joint, after the two shells  38  are combined together, they form a cylindrical barrel body, and a gas cylinder can be placed inside the bottom base  3 ; after the gas cylinder is connected to the gas valve  10 , the gas cylinder can supply air for the burner  1 ; wheels  34  are provided on the rear side peripheral wall of the bottom surface  39 , and a column hole  35  is provided on the top surface  40  for column inserting purpose, and the column hole  35  is set at the front side of the top surface  40 ; a hollow column holder  37  is arranged in the column hole  35 , and the column holder  37  is fixed within the column hole  35 ; the peripheral wall of the column holder  37  is provided with grooves  44  along the axial direction, and an adjustable pipe clamp  36  is set at the lower end of the column holder  37  and inside the bottom base  3  which is extended to the lower end of the bottom base  3 , and after the standing column  2  is plugged into the column hole  35 , screws can be locked into the standing column  2  from the grooves  44 , and by tightening nuts on the pipe clamp  36 , the standing column  2  is fixed within the column holder  37 . 
     Furthermore, a chain  45  is set in the bottom base  3  for fixing the gas cylinder, and two ends of the chain  45  are connected to the framework  46  by buckles which are detachable. 
     Referring to  FIG. 5 , the pipe fittings  5  are tee pipe fittings, and the pipe fittings  5  comprise a left and a right pipe pieces  47  which are symmetrical to each other, and the pipe pieces  47  further comprise a column fixing part  41  for connecting with the standing column  2  and a beam fixing part  42  for connecting with the two beams, and the beam fixing part  42  is arranged on the front and rear sides of the column fixing part  41 , and cross-sectional shape of the column fixing part  41  and the beam fixing part  41  are both semi-circle; and the inner diameter of the column fixing part  41  is equal to the outer diameter of the standing column  2 ; and the inner diameter of the beam fixing part  42  is equal to the outer diameter of the beam, and after combing the two pipe pieces  47  together, the cross-section of the column fixing part  41  forms a circle, and the cross-section of the beam fixing part  42  forms a circle. Two first screw holes  49  are provided on the column fixing part  41  along the axial direction, and two second screw holes  50  are provided on the two beam fixing parts  42  with one on each side respectively, and a third screw hole  51  is provided on the standing column  2  at the corresponding position to that of the first screw hold  49  on the lower end of the column fixing part  41 , and the two pipe pieces  47  can hold the column and the beam by inserting bolts into the first screw hole  49 , the second screw hole  50  and the third screw hole  51  and using nuts to tighten the bolts, so that the column, the beam and the pipe pieces are fixedly connected. 
     Referring to  FIG. 6 , the first embodiment of the ignition control device  6  can utilizes a manual type gas stove ignition switch  16  of the prior art, and an ignition switch shaft of the gas stove ignition switch  16  extends to the rear end of the base  15 , and a rotary nob  17  is provided on the ignition switch shaft of the gas stove ignition switch  16 , and the rotary nob  17  is set at outside of the rear end of the base  15 , and the electrode  7  is connected to the ignition wire of the gas stove ignition switch  16 , and the thermocoupler  22  is connected to a signal wire of the gas stove ignition switch  16 , and an outlet of the gas stove ignition switch  16  is connected to the first ejector pipe  31  by pipes, and an inlet of the gas stove ignition switch  16  is connected to the gas valve  10  by pipes. 
     The manual type gas stove ignition switch  16  can also utilize the SRSV03 gas ignition device which is produced by SHINERICH INDUSTRIAL Co., Ltd. (the burner in China Patent No. CN 20052000535 U). 
     Referring to  FIG. 7 , the ignition control device  6  comprises an automatic gas control  18 , a solenoid valve  19 , a battery box  54 , a valve dead plate  53  and an anti-dumping switch  55 , and the power line of the automatic gas control  18  is connected to the battery box  44  which provides power for the ignition control device  6 . The solenoid valve wire end of the automatic gas control  18  is connected to the solenoid valve  19 . The anti-dumping switch  55  and the thermocouple  22  are connected to a signal sensing wire end of the automatic gas control  18  respectively. The first ejector pipe  31  is connected to an outlet of the solenoid valve  19  by gas pipes, and an inlet of the solenoid valve  19  is connected to the gas valve  10  by gas pipes, and an ignition wire of the automatic gas control  18  is connected to the electrode  7 ; a key-press pad  20  is fixedly connected to the rear end of the base  15 , and the key-press pad  20  is connected to a control wire end of the automatic gas control  18 , and a faceplate  21  is provided on the key-press pad  20 , and the faceplate is bolted on the key-press pad  20 . The ignition control device  6  can also be connected following the wire connecting arrangement of the ignition control device in China Patent No. CN 20052000535 U. 
     When in use, by rotating the rotary nob  17  or pressing the ignition key on the key-press pad  20 , gas goes into the combustion chamber  11  via gas pipes and the ejector pipe  14 , which the electrode  7  discharges to ignite, so that the gas is burned on the upper end surface of the sintered mat  8 . Because the gas is burned on the sintered mat  8 , an infrared effect can be achieved. When heat is reflected downward by the second reflector  52  and the first reflector  9 , an effect of efficiently radiated heat can be achieved. 
     As a result of no open flame being used in the present invention, the thermal efficiency is increased over 30%, and even in a windy environment, the function of the burner is not effected, and the ignition control device uses a module design, which makes the maintenance more convenient. 
     One skilled in the art will understand that the embodiment of the present invention as shown in the drawings and described above is exemplary only and not intended to be limiting. 
     It will thus be seen that the objects of the present invention have been fully and effectively accomplished. The embodiments have been shown and described for the purposes of illustrating the functional and structural principles of the present invention and is subject to change without departure from such principles. Therefore, this invention includes all modifications encompassed within the spirit and scope of the following claims.