US3734681A

US3734681A - Gas smooth top range

Info

Publication number: US3734681A
Application number: US00178408A
Authority: US
Inventors: R Perl
Original assignee: Tappan Co
Current assignee: White Consolidated Industries Inc
Priority date: 1970-06-15
Filing date: 1971-09-07
Publication date: 1973-05-22
Anticipated expiration: 1990-05-22

Abstract

The range has plural radiant burners with individually associated heat exchangers and a common pressurized exhaust system. Each burner has a supply air tube the inlet end of which is obstructed by a coil spring which is variably expanded to act as an adjustable shutter regulating the amount of air that enters through its turns in response to actuation of the gas control valve for the burner. The burners have center simmer sections for low heat and single gas lines with port controlled terminals which variably direct the gas to the center simmer sections or to the main burner sections depending upon the rate of delivery of the same. A safety circuit prevents flow of gas to the range except when exhaust fans are properly operating, and a taut wire exposed to heating by all burners expands when any is above a selected temperature to signal such condition.

Description

United States Patent [191 Perl [ 1 May 22,1973

[ GAS SMOOTH TOP RANGE Richard L. Perl, Mansfield, Ohio [73] Assignee: The Tappan Company, Mansfield,

Ohio

[22] Filed: Sept. 7, 1971 [21] Appl. No.: 178,408

Related U.S. Application Data [62] Division of Ser. No. 45,991, June 15, 1970, Pat. No.

[75] Inventor:

[56] References Cited UNITED STATES PATENTS 9/1955 Ray ..431/242 X 9/1971 Reid ..l26/39 J Primary ExaminerCarroll B. Dority, Jr. Attorney-Donnelly, Renner, Maky & Olto [57] ABSTRACT The range has plural radiant burners with individually associated heat exchangers and a common pressurized exhaust system. Each burner has a supply air tube the inlet end of which is obstructed by a coil spring which is variably expanded to act as an adjustable shutter regulating the amount of air that enters through its turns in response to actuation of the gas control valve for the burner. The burners have center simmer sections for low heat and single gas lines with port controlled terminals which variably direct the gas to the center simmer sections or to the main burner sections depending upon the rate of delivery of the same. A safety circuit prevents flow of gas to the range except when exhaust fans are properly operating, and a taut wire exposed to heating by all burners expands when any is above a selected temperature to signal such condition.

3 Claims, 7 Drawing Figures EXHAUST I. i rill l 1 I08 14 41.255 2'2 7'6 7'4 46 15 PATENTEL #1Y22l975 SHEET 2 OF 3 PATENTEU M2 3; 734.681

SHEET 3 OF 3 L\ La; f'gu GAS SMOOTH TOP RANGE This is a division of application Ser. No. 45,991, filed June 15, 1970 and now U.S. Pat. No. 3,646,927.

This invention concerns closed or smooth top ranges in which gas burning devices selectively and controllably serve as plural heat sources for cooking in utensils and the like placed on the top surface of the range.

The presently preferred combination of burner and smooth top in such an appliance uses for the latter a glass ceramic material having an essentially zero temperature coefficient of expansion and a high intensity radiant gas burner having a powered air supply. When plural burners are provided, the traditional minimum for surface cooking in a domestic range being four, the hot exhaust from the appliance should not be discharged directly to the room, and various expedients have been proposed for cooling the exhaust within the unit to a safe and tolerable level prior to room discharge to obviate the need for exterior venting. U.S. Pat. NO. 3,241,542 shows, for example, a substantial vertical flue for the purpose in such a range, and in U.S. Pat. No. 3,494,350 there is disclosed a rotary heat exchanger commonly serving the four burners which are used.

It is a primary object of the present invention to provide a combined gas burner and heat exchanger which is particularly suited for this closed top range use and forms an operating sub-assembly in which the burner and exchanger are very closely structurally united. As a result, the device is very compact and actually requires little added space in a rough-in box, for example.

The exchanger, basically, brings ambient air flowing to the burner into heat transfer relation to the combustion gases from the latter, and it is a further object of the invention to improve the efficiency of this section of the device. The ability of the incoming air to extract heat from the outgoing exhaust gases is of course an important determinant in sizing the exchanger section, and it will be understood that in a full range employing four or more heat sources, with the new individual exchanger sections for the burners, the benefits are correspondingly multiplied.

It is also an object to provide such a burnerexchanger device for a unit having high and low conditions of operation, preferably in a configuration defining a main annular port section and a center section therein which may be operated alone for relatively low heat demands, such as in a simmer position of adjustment. This advanced control has, moreover, been provided with a single gas supply line to the burner, as compared to the two line arrangement generally found in burners equipped with center simmer sections.

With further regard to the full range, especially with a glass ceramic top or equivalent, there has been concern for safety in the event of breakage of the top, and various measures have been proposed to ensure that the burners are fully disabled from operation if such condition should exist. The provision of a safety on this order is another object of the present invention.

It is also thought desirable that the user should be alerted when any burner is hot, since even with the glass ceramic top, the material is preferably translucent and there is a definite lag between the time a burner is turned on and the usual red image becomes visible at the top surface, and again between turning off of the unit and return to substantially room temperature.

There can be significant heat at the top surface in these periods, and a still further object of this invention is to provide an indicator control which will tell the user when there is any burner in the range above a selected temperature, regardless of the control settings.

Other objects and advantages of the present invention will become apparent as the following description proceeds.

To the accomplishment of the foregoing and related ends the invention, then, comprises the features hereinafter fully described and particularly pointed out in the claims, the following description and the annexed drawings setting forth in detail certain illustrative embodiments of the invention, these being indicative, however, of but a few of the various ways in which the principle of the invention may be employed.

In said annexed drawings:

FIG. 1 is a perspective view of a smooth top range in accordance with the present invention and on a relatively reduced scale;

FIG. 2 is a side elevation of the range partially broken and showing in transverse section one of the new burner devices and the associated control;

FIG. 3 is a top plan view of half of the range, which is symmetrical about its transverse center line, with the glass top removed and the enclosure at the valve area broken away to expose the valving;

FIG. 4 is a fragmented top plan view of one component of the heat exchanger section combined with the burner;

FIG. 5 is a vertical section on an enlarged scale of the gas supply section of the burner;

FIG. 6 is a diagram of the wiring of the range; and

FIG. 7 is a simplified plan view of the rough-in box and burners in which an indicator control is shown.

Referring now to the drawings in detail, the range of the invention is designated generally by reference numeral 10 in FIG. 1 and shown as incorporated in kitchen counter structure 11. The top of the range is preferably a single sheet or layer of glass ceramic material 12 which is substantially transparent to infrared radiation and has for practical purposes in this application a zero temperature coefficient of expansion.

The glass layer is the top closure of a relatively shallow box housing 13 fitted with a control section 14 at the front edge within which there are four vertically oriented valves, to be later described more in detail, re-

spectively actuated by control knobs 15. The range front wall is provided with openings 16, and the exterior configuration is completed by a hollow backsplasher at the rear having a horizontal discharge slot 17 at the top front in which a decorative grill 18 or the like is mounted. As will also appear more fully, the op eration of the range involves an intake of air through the front louvered openings for the burner devices and exhaust of the combustion gases through the backsplasher slot.

The four valves of course indicate that the unit contains four burner devices and, as earlier explained, the mechanical design is symmetrical with respect to the plane of the transverse center line. The details of the right half of the range shown in FIGS. 2 and 3 will thus 1 A sheet metal pan 21 is applied over the main bottom exterior of the box 13 and forms the actual bottom wall of the appliance, while defining with the box an enclosed chamber 22. The burner area is separated from the forward control section by a vertical partition 23 which extends across the width of the unit. In the main area of the box behind this partition at the right there are the two

burners

19, 20, a motor driven exhaust fan 24, and two

air tubes

25, 26 extending from the partition horizontally and then vertically to the box floor at points respectively adjacent the burners. The fan has its intake 27 at an opening in the floor and its outlet connected to one-half of a discharge duct 28 extending to the rear and then upwardly through the backsplasher to the discharge slot 17 in the same.

With regard now to the design of the burner or, more exactly, burner-exchanger combination, this device is made up of a series of inexpensively formed sheet metal parts in vertical stacked assembly. The bottom piece 30, referring to FIG. 2, is a circular pan having a center aperture 31 and a relatively raised bottom 32 leaving a ring channel form about the outer periph cry in which there are slots or holes 34. The outer wall of this pan is provided with inner dimples 36 serving as stops beneath the top edge for application of a plate 37 having the same outside diameter and a similar dimpled outer flange or wall 38. Plate 37 is nested at the exterior within the bottom pan and further has a center opening 39 of larger diameter than the pan aperture 31. Next in succession is a small baffle 40, with a center aperture that does correspond to aperture 31 and shaped so that its main body section is offset vertically with respect to both its center apertured section and its outer edge section.

It will be noted that the outer diameter of the small baffle is less than that of the pan and plate, and the inner edge of the pan is crimped over the corresponding registering edge of the baffle as shown. A closure disc 44 of the same smaller outside diameter is applied to the top of the small baffle 40, and this disc is formed with a relatively small center hole 45 and a series of raised louvers 46 which extend normal to radii of the disc in the same rotative direction. Spacers 47 are secured between these elements for rigidifying the structure, with some baffling effect, and the abutting edges of the small baffle and disc are welded together.

The assembly of circular pan 30, plate 37, small baffle 40, and louvered disc 44, is repeated in building the stack as shown by the primed reference numerals, with a gasket 48, however, preferably interposed at the joint of the inner edges of pan and plate 37'. Added to this full repetition are one further pan 30" and plate 37", and then a deeper drawn burner pan 49 as the uppermost component.

The burner pan has a center opening in register with that of the pan 30", with the edge of the latter crimped over the former at 31", and a stepped body form providing intermediate wall 51, an outer ring portion in which there are openings 53, and a relatively higher wall which nests in the plate 37". The wall of the burner pan is moreover flanged outwardly at its top 55 and, with the bottom pan 30 of the stack resting on the bottom of the box 13, the burner pan top flange is closely opposed to the underside of the top glass plate or layer 12. A gasket 56 is placed between the last two opposed surfaces for sealing the unit to the glass.

A center spacer 57 of inverted pan form having holes 58 in its vertical wall is secured to the burner pan over the center opening of the same and supports a burner screen 59. This screen in turn supports a body 60 of ceramic brick or tile, in one or more pieces and having a multiplicity of vertical ports, and overlying the top of the same is a metal retainer ring 61 which is cut to provide predetermined port areas, namely, a center circular section 62 and what is essentially an outwardly spaced annular section 63. For a purpose to be explained, four equally spaced radial reliefs 64 are provided in the metal masking section separating the center section and the outer annular section, which is considered the main port section.

Gas is supplied to the burner device 20 through valving, which will be described below, and a steel tube 65 which extends from the forward control section 14 of the range through the bottom chamber 22 to the vertical center line of the burner and then upwardly to a closed end within the same as best shown in FIG. 5. The end of supply tube 65 is closed by a plug terminus 66 of the same outside diameter and having plural orifices 67 in the side wall at an elevation above the lowermost louvered disc 44. This end extent of the supply tube within the burner device is enclosed by a length of larger diameter tubing or surround 68 spaced about the same extending in effect from the closed bottom closely through the flanged center hole 45 of the disc 44 to an open and relatively reduced end 69 between this disc and the next succeeding louvered disc 44'. Orifices 70 of larger diameter than the orifices 67 are provided in the tubing 68 respectively in register with the former, and the reduced upper end 69 of the tubing extends with clearance into another length of tubing 71 which proceeds upwardly closely through the uppermost louvered disc 44' to a supporting attachment with the burner support and spacer 57. A metal rod 72 extends from an upper end contact with burner screen 59 to contact with the top of the burner tube plug 66 to serve as a heat conductor therebetween for a purpose to be set forth in the following.

Reverting to FIG. 2, it will thus be evident that this gas supply assembly within the burner 20 extends freely, that is, with appreciable clearance, through the center apertures at 31, 31' and 31", while cooperably engaging the louvered discs 44 and 44' to block any central flow through the same at these levels.

The air tube 26 previously mentioned associated with the rear right burner 20 communicates through an opening in the floor of the box 13 with a pear-shaped housing 73 applied to the underside of the floor, and the latter is provided with openings 74 which permit the air to enter the bottom of the burner-exchanger assembly. The dashed arrows in FIG. 2 indicate this entry and flow reversely over pan bottom 32 and small baffle 40 to and through the directionally louvered openings 46 in the first closure disc 44. These openings impart a swirling movement to the flow, which continues upwardly past the gas supply holes 70 and reversely over pan 30' and baffle 40' to the further louvered disc 44'. The latter produces further rotative movement of the upflow, now of course including gaseous fuel if supplied through the holes 70, and continues over the inner or central path to the burner pan at the underside of the ceramic body. The gas-air mixture will flow through the unblocked port areas defined by the top retainer or mask for ignition and heating of the body to incandescence to produce the desired infrared radia tion.

The sealing of the burner pan 49 to the glass contains the hot combustion gases and these are caused to flow in the manner indicated by the full line arrows. More particularly, the flow is downwardly through the pan relatively at the outside openings 53 of the same, reversely over the opposite sides of plate 37" to outer pan openings 34", and then similarly through the remainder of the stack. The bottom of the rough-in box 13 is also provided with openings 75 in register with holes 34 in the bottom pan, and a large generally rectangular exhaust pan 76 is applied to the exterior of the bottom to contain in spaced relation the air intake housing 73 and form an exhaust collector chamber.

This exterior exhaust pan 76 communicates with the opening 27 at the intake of the fan 24, and the latter is thus operative to maintain the burner device under negative pressure for the described air and exhaust flows. Within the exchanger section, the counterflows of the air and exhaust are radial as well as vertical, with the noted swirling component in the former. When gas is supplied at the holes or ports 70, a part of the exchanger serves as a mixing chamber for the fuel and air.

The mechanical design of the gas supply tube disclosed provides the desired two control settings for the burner noted at the outset through ordinary valve control of the velocity of the gas. With the gas delivered at high velocity, for example, at a rate corresponding to 6,500 to 8,000 BTU per hour, the impingement against the closed end of the plug 66 will forcibly divert all of the gas outwardly through the holes 67 and the registering holes 70 to encounter the upward swirling air and proceed therewith through the outer main port section 63 of the burner. At a lower velocity, for example, at a rate equivalent to that of 500 to 600 BTU per hour, the gas issuing from the plug holes 67 is pulled upwardly by the slightly negative pressure which exists at the burner surface through tubing 71 to the center or simmer section 62 for the reduced or low heat setting. In this case or condition of operation, combustion air is also drawn into tubing 71 over reduced end 69 of the lower tubing 68.

In the operation of the burner, the supply air to the same becomes preheated in the exchanger section and expands, and, without alteration of the supply, there is a tendency for the air-gas mixture to become relatively rich. The general heating of the environment does cause some rise in the temperature of the gas as it is delivered to the burner, as a compensating influence, and the rod 72 in acting as a heat bridge between the burner screen 59 and plug 66 very significantly accelerates and adds to this effect. Accordingly, the weight of the fuel is automatically reduced through this heating to more closely maintain the selected air and fuel ratio notwithstanding the noted weight loss in the air, and this benefits ignition and permits operation with less than the excess air which would be included ordinarily in the design. The flow rate reduction also provides protection against overheating of the top glass.

The front burner 19 at the same side is served by its own air tube 25 and comparable intake housing 73, while its exhaust is also collected in the pan 76 for delivery to the fan 24 and the noted discharge. As also noted earlier, this burner is of somewhat smaller size, and a modified masking retainer 61 is used. In this case, the intervening band of metal between the center simmer section 62' and the annular main port section 63' does not have the reliefs 64 of the latter. The burners are ignited electrically by the paired

electrodes

77 and 78, and in the case of the large burner 20, the reliefs provide a better bridge for assured flashing to the center simmer section. With the smaller burner, the separation is not great enough to require this assist.

The two

burner devices

19 and 20 are respectively controlled by

duplicate valves

79 and 80, and all such valves in the range are served by a gas line 81 extending horizontally in the control section 14 and adapted for connection to an available external supply through a conventional solenoid valve and pressure regulator. Each valve actuating shaft 82 carries a cam having a flat 83, a notch 84, and a curved part 85. These cams are opposite the open ends of the

air tubes

25 and 26 forwardly of the partition 23, and extending from fixed pins 86 traversing the tubes are yokes 87 which engage about the shafts 82 below the cams. These pins also serve as stops for coil springs 88 which project from within the tubes to bear against retainers 89 slidable on brackets 90 mounting rollers 91 vertically in contact with the cam edges.

The brackets 90 have forward end slots 92 permitting them to move relatively on the valve shafts and extend, together with the retainers 89, through slots 93 in the partition 23, so that the two pieces can move together in and out relative to the ends of the tubes and hence with expansion or compression of the springs 88. The normal separation between the brackets and the retainers is determined by adjusting screws 94.

The foregoing cam-spring devices provide automatic air regulation upon actuation of the gas valves, since air entering the open ends of the tubes must proceed through the turns of the springs 88 and the spacing of the same will vary depending upon the state of compression or expansion of the springs. The valves in respect of the gas control are of the usual plug type, and the spring action precludes stopping of the valve between the lowest main setting and the center simmer setting in the movement of the control from the former to the latter condition.

With particular reference to FIG. 3, in which the valves 79 and are both shown in off condition, it will be seen that turning either counterclockwise will first push the associated roller inward against the spring pressure until it seats in the cam notch 84. This is made to correspond with the simmer or low setting of the controlled burner at the gas valve and some compression of the air tube spring is effected for predetermined ambient air inflow to the burner. Further turning of the valve shaft will increase the gas delivery opening to a main or maximum condition for the main port operation over the cam part which has a relatively reducing radius, so that the roller can advance and permit the spring behind the same to expand for increased air flow into the associated air tube. The coil springs thereby act as shutters for adjustment of the air intake responsive to the settings of the gas supply valves.

Two normally open control switches 98 are mounted between the

valves

79 and 80, and resilient arms 97 bridge the brackets in engagement with the operating plungers of these switches. Only one switch is evi-' dent in FIG. 3, since the other is mounted directly beneath the same, with both however shown in the wiring diagram of FIG. 6. It will be seen from FIG. 3 that any adjustment of either valve will cause the two leafs to cant or, if both are actuated, to move fully away from the switch plungers, and in both cases the plungers are released to close the switches.

As shown in the full range diagram of FIG. 6, switches 98 first control the four electrode pairs 77, 78, 77, 78' for ignition, with any valve actuation causing energization of all ignitors. Another circuit is closed simultaneously through the control wire 100 of a normally closed hot wire relay 101 in common series with the motors of the two fans or blowers 24, 24' and a further circuit is completed through the relay 101 itself to energize the solenoid valve 102 which controls the flow of gas to the entire range. An ON indicating light 103 is included, and the wire 100 of the hot wire relay will preferably be located at some point in the ambient air stream to be responsive to the circulation produced by operation of the fans. For example, it can be positioned in the control section area where the room air is drawn in, and unless there is sufficient inflow of this relatively cool air, the wire will heat due to current flow therein and expand to open the normally closed relay 101 and de-energize solenoid valve 102.

Another indicating control is shown which is further depicted in FIG. 7 and utilizes the fact that the top glass layer will experience substantially no thermal expansion in the operation of the appliance. A wire 104 having a positive temperature coefficient of expansion is stretched suitably through the unit over the edges of all four

burners

19, 20, 19', and secured at a free end to a switch actuating arm 105. The taut wire normally holds the arm against the plunger of a switch 106 mounted on the glass 12, so that it is and remains fixed, to hold the switch contacts open, and significant heat in any burner causes the wire 104 to expand and, releasing the arm 105, permit closure of the switch. Accordingly, regardless of the valve settings, a HOT lamp 107 in this circuit will be illuminated whenever any burner is above a selected temperature, and this value will of course be determined by the level of sensible heat at the top surface which is considered to be to]- erable.

The full range in the disclosed embodiment, accordingly, comprises four burners with in dividual heat exchangers and a shared or common exhaust system in which fans are located to pressurize the unit. As noted earlier, this particular arrangement maintains the bumers under negative pressure, and holes 108 in the pan 76 provide an air flow over the bottom for cooling and to produce a slightly negative pressure within the box as well. Since the existence of this negative pressure is another indication of the fan operation, it might be used as a condition for the above described safety interlock of the burners, for example, by means of a suitable pressure responsive switch controlling the main gas line solenoid valve.

It will also be appreciated that the range could be made to operate by pressurizing the supply air instead of the exhaust, with appropriate modification of the gas supply to the individual burners and sealing of the exhaust part of the system to control the discharge in this relatively reversed arrangement.

I, therefore, particularly point out and distinctly claim as my invention:

1. In a gas burner having a center port section and an outer port section, a gaseous fuel supply line having a terminus at the burner with lateral discharge orifices, a surround for said terminus spaced therefrom and having orifices respectively in alignment with the terminus orifices, the surround continuing to an outlet proximate to the center burner section, and enclosure means about the surround extending to the region of the outer port section, with fuel issuing at relatively low velocity from the terminus orifices being confined in and proceeding through the surround to the center section and at relatively high velocity being forced outwardly through the surround orifices for supply to the outer burner section through the enclosure means.

2. A gas burner as set forth in claim 1, wherein the enclosure means has an air supply for mixing therein of the gaseous fuel and combustion air, and there is communication between the enclosure means and the interior of the surround for air supply to the latter in the delivery of the low velocity fuel through the same to the center burner section.

3. A gas burner as set forth in claim 1, including a heat bridge within the burner extending from a port section thereof to the fuel supply line to raise the temperature of the fuel and thereby effect a relative reduction in its weight as the burner temperature rises.