JP2004105203A - Fryer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent combustion failure of a burner by block of the burner. <P>SOLUTION: The fryer 1 comprises left and right burners 20L and 20R, one turbo-fan 71 for feeding combustion air, feed air distributor 89 connected to an exhaust port 71a of the turbo-fan, left and right blast tubes 72L and 72R branched from the air distributor 89, a mixing tube 74 connected to the left and right burners 20L and 20R, two fan detection pressure guide tubes 35 connected to the exhaust port 71a, burner detection pressure guide tubes 36L and 36R connected to the blast tubes 72L and 72R respectively, differential pressure switches 34L and 34R connected to the tips of the detection pressure guide tubes 35 and 36, and a controller 100 for detecting the closed state of the left and right burners 20L and 20R based on the detection signals of the differential pressure switches 34L and 34R and executing the control for preventing incomplete combustion. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fryer for distributing and supplying combustion air from a single fan to a plurality of burners for combustion.
[0002]
[Prior art]
For example, in the food service industry such as a fast food restaurant, a commercial fryer is used for cooking fried foods such as potatoes and chicken (for example, see Patent Document 1).
As shown in FIG. 18, the fryer 201 is provided with oil tanks 210L and 210R on the left and right, respectively, which are filled with cooking oil for frying ingredients, and an all-primary pneumatic plate burner having a flame opening surface from the outside of the oil tanks 210L and 210R. The cooking oil is heated by burning 220L and 220R independently. For example, when cooking is performed only in the left oil tank 210L, only the left burner 220L is burned.
[0003]
The combustion gas generated from each burner 220L, 220R is discharged from a common exhaust duct 233.
On the other hand, the air used for burning the burners 220L and 220R is supplied by one common sirocco fan 271. A wind pressure switch 234 </ b> F for detecting a failure of the fan 271 is provided at a jet port 271 a of the fan 271 via a fan detection pipe 235.
When the wind pressure at the outlet 271a of the fan 271 exceeds a predetermined pressure, the diaphragm 234Fa is deformed (transformed from a solid line to a broken line in FIG. 18), the micro switch 234Fb is pressed, the wind pressure switch 234F is turned on, and the controller 100 is turned on. Detects that the fan 271 is blowing air. If the turning off of the wind pressure switch 234F is detected during the operation control of the fan 271, it is determined that the fan 271 has failed.
[0004]
[Patent Document 1]
JP-A-2002-85268
[Problems to be solved by the invention]
However, in the fryer 201 having such a configuration, a large amount of oil smoke is generated from the oil tank 210 and floats around the appliance. Therefore, when the burner 220 sucks the combustion air from the fan 271, the smoke is sucked together with dust. Oil may adhere to the burner port of the burner 220 and dust may be easily clogged, which may result in poor combustion due to clogging of the burner port.
Further, in the case where the oil tank 263 for filtering the cooking oil in the oil tank 210 is provided, the fan 271 is close to the tank inlet 263b of the oil tank 263, so that the oil smoke from the oil tank 263 is also sucked, and the flame outlet of the burner 220 is opened. It was easier to clog. This tendency is particularly remarkable in the all-primary pneumatic plate burner 220 because many small flame openings are formed and are easily clogged.
Further, the exhaust duct 233 may be blocked by some foreign matter, and the exhaust may be blocked.
[0006]
As described above, in the conventional fryer 201, even if the burner 220 and the exhaust duct 233 are closed, the wind pressure of the outlet 271a of the fan 271 is maintained high as long as the fan 271 is rotating, and the wind pressure switch 234F is turned on. Had been maintained. As a result, it has been difficult to prevent incomplete combustion due to blockage of the supply / exhaust passage only by determining the signal from the wind pressure switch 234F.
An object of the present invention is to solve the above-mentioned problem and to prevent poor combustion due to blockage of a supply / exhaust passage.
[0007]
[Means for Solving the Problems]
The fryer according to claim 1 of the present invention which solves the above-mentioned problems,
An oil tank filled with cooking oil, a plurality of burners for independently heating the cooking oil in the oil tank, a common fan for supplying combustion air to each of the plurality of burners, and an outlet of the fan. A single common air supply path and a plurality of branch air supply paths branched from the common air supply path and connected to each burner,
Differential pressure detecting means for detecting a differential pressure between the internal pressure of the common air supply path or the fan outlet and the internal pressure of the branch air supply path is provided in each of the branch air supply paths,
The gist is to perform incomplete combustion prevention control according to the detected differential pressure.
[0008]
The fryer according to claim 2 of the present invention is the fryer according to claim 1,
The gist is that an all-primary pneumatic plate burner having a plurality of flame ports formed on a plane is used as the burner.
[0009]
The fryer according to claim 3 of the present invention is the fryer according to claim 1 or 2,
The gist is that a turbo fan is used as the fan.
[0010]
The fryer according to claim 1 of the present invention having the above configuration detects a differential pressure between the internal pressure of the fan outlet or the common air supply path and the internal pressure of the branch air supply path for each branch air supply path, The differential pressure between the pressure on the fan side and the pressure on the burner side is detected for each burner.
If the differential pressure detected by the differential pressure detecting means is lower than a predetermined pressure, it is determined that the supply / exhaust flow path of the burner is blocked, and the supply of fuel gas is stopped or an alarm is sounded. Perform combustion prevention control.
[0011]
Further, in the fryer according to the second aspect of the present invention, a flame is formed on the plate of the all-primary pneumatic plate burner to heat the cooking oil in the oil tank. This burner has the advantage that the orientation of the combustion surface is not restricted and thus the degree of freedom in arrangement is high.On the other hand, the flame forming surface is easily clogged. The advantage of can be fully utilized.
[0012]
Further, in the fryer according to the third aspect of the present invention, a large differential pressure can be obtained by the differential pressure detecting means because a turbo fan having a high wind pressure is used for the same air volume.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
In order to further clarify the configuration and operation of the present invention described above, a preferred embodiment of the fryer of the present invention will be described below.
[0014]
A commercial fryer according to an embodiment of the present invention will be described with reference to FIGS. This fryer is a split vat type in which an oil tank (bat) is divided into right and left, and different foods can be simultaneously cooked in each oil tank. In the following description and drawings, when the left and right are symmetric, L and R are added to the end of the reference numeral, but are omitted when the left and right are not distinguished.
[0015]
As shown in FIG. 1, the fryer 1 includes an oil tank 10 provided at the upper part of the utensil and filled with cooking oil, a burner 20 provided to face an oil tank bottom part 11 from the outside from outside to heat the cooking oil, and an oil tank 10. A burner case 80 integrated at the lower portion by screwing to accommodate and support the burner 20, a supply unit 70 for supplying combustion air and fuel gas to the burner 20, a combustion gas from the burner 20 is guided to the outside of the body, and on the way. The main body case 2 includes an exhaust passage 30 that heats cooking oil, a controller 100 that controls cooking time and cooking temperature, and a filtering device 60 that is provided below the oil tank 10 and filters cooking oil.
[0016]
As shown in FIGS. 2 to 4, the oil tank 10 is formed with a flange 17 formed by bending the entire circumference of the upper end outward, and also divides the oil tank 10 into left and right left oil tanks 10L and right oil tanks 10R. A plate 10a is provided.
The wall surface constituting the oil tank 10 is roughly divided into a bottom portion 11, an oil residue storage portion 12, a front portion 13, a rear portion 14, a left side portion 15, and a right side portion 16.
Step portions 15 a and 16 a forming an exhaust passage 30 are formed on the left side surface portion 15 and the right side surface portion 16 of the oil tank 10. Further, a U-shaped bottom net support 10b that supports a bottom net 44 described later is provided on the left and right of the oil tank division plate 10a at the same height position as the steps 15a and 16a when viewed from above. In addition, as shown in FIG. 1, a front inclined portion 13 a that is inclined backward and downward is formed on the front surface portion 13.
[0017]
The bottom surface portion 11 of the oil tank 10 is a flat surface inclined downward from the lower end of the front surface portion 13, and an oil residue housing portion 12 for storing oil residue between the oil tank 10 and the rear surface portion 14 is formed at the rear end. The oil residue housing portion 12 is formed in a groove shape extending in the left-right direction.
[0018]
The main body case 2 is provided with a mounting surface portion 2c for supporting the flange 17 of the oil tank 10 integrated with the burner case 80 at the upper front side and the upper left and right sides. The upper opening 2d serving as the opening of the mounting surface 2c is formed slightly larger than the wall surface of the oil tank 10 and the burner case 80 in the front-rear direction so that the oil tank 10 and the burner case 80 are easily dropped.
Further, a door 2a is provided on the front of the main body case 2. In addition, the left side of FIG. 1 is the front of the utensil, and is an area where a worker performs a cooking operation.
[0019]
As shown in FIG. 2, the burner case 80 fixes the burner 20 at a predetermined position. The burner case 80 is fixed at a lower end of the side plate 81 to a side plate 81 facing the side surfaces 15 and 16 of the oil tank 10 at a predetermined interval. A lower plate 82 formed substantially parallel to the oil tank bottom 11 (FIG. 1), and a front opening 85 (FIG. 3) serving as an entrance and exit of the burner 20 formed at the front by the side plate 81 and the lower plate 82. And a front plate 83 fixed to the side plate 81 and the lower plate 82, and a rear plate 84 (FIG. 1) fixed to the rear surface portion 14 of the oil tank 10 and bent up and down in a U-shape.
[0020]
The burner case 80 is formed airtight by fixing the constituent plates 81 to 84 with bolts and nuts, respectively. As shown in FIG. 2, the upper end of the side plate 81 is fixed to the left and right side surfaces 15, 16 above the steps 15a, 16a.
[0021]
As shown in FIG. 1, the burner 20 is an all-primary pneumatic burner provided with a ceramic plate 22 having a plurality of flame openings as a combustion surface (flame surface 22 a). Are provided facing each other at a predetermined interval from each other, and a combustion chamber 29 is formed therebetween. In other words, the flame outlet surface 22a is inclined downward and backward in the same manner as the oil tank bottom portion 11. As will be described in detail later, the burner 20 is provided detachably from the burner case 80.
[0022]
The combustion chamber 29 is provided with an ignition electrode rod 51 for igniting the burner 20 and a frame rod 52 (FIGS. 14 and 15) for detecting a flame state, facing the ceramic plate 22. The ignition electrode rod 51 and the frame rod 52 are made of the same component, and an identification joint 98 is fitted to the end of the ignition electrode rod 51 to distinguish them.
[0023]
FIG. 4 is an AA cross-sectional view of a part of the fryer 1 as viewed from the front (see FIG. 1 for a cutting line AA) and shows the burner 20 and its surrounding components in detail.
The burner 20 includes a flat box-shaped burner main body 23 having an open upper surface, and a ceramic plate 22 that covers the upper surface of the burner main body 23. A mixing chamber 21 for mixing fuel gas and combustion air is provided therebetween. It is formed.
[0024]
The burner body 23 has a step 23a formed by bending the entire upper periphery outwardly, and further bending the upper end of the step 23a outward to form left and right ends 23b, a front end 23c, and a rear end 23d (FIG. 1, FIG. 3) is formed. The bottom surface 23g of the burner main body 23 is formed substantially parallel to the oil tank bottom surface 11, that is, inclined downward and rearward.
As shown in FIG. 3, the left and right end portions 23 b extend in the front-rear direction, are welded to lower end surfaces 26 a of left and right outer pressing plates 26 described later, and are formed as flanges 20 a of the burner 20.
[0025]
The front end 23c and the rear end 23d are each bent downward to form a mounting surface for the burner body 23, as shown in FIGS. 1, 3, and 5, and the rear end 23d is shown in FIG. As shown, grooves 23e are formed at both left and right ends of the mounting surface so that a rear end 23d does not hit a rail 90 described later.
An entrance 23f is opened in the front surface of the burner main body 23.
In addition, before and after the burner 20, there are provided front and rear packings 87 for preventing the combustion exhaust gas from leaking.
[0026]
As shown in FIG. 4, a mixing chamber separation table 24 for dividing the mixing chamber 21 into left and right mixing chambers 21L and 21R is welded to the center of the bottom surface of the burner body 23. Step portions 24a are formed on both left and right sides of the upper part of the chamber separation table 24. As shown in FIGS. 3 and 4, the ceramic plate 22 is divided into six front, rear, left, and right parts. The ceramic plate 22 has a step part 24a of the center mixing chamber separation table 24 and a step part 23a of the burner main body 23 on the left and right sides. Is placed. In this manner, the burner 20 is divided into left and right burners 20L and 20R.
[0027]
An inner pressing plate 25 extending to the rear of the burner 20 and forming a groove in the center is placed on the mixing chamber separation table 24, and extends to the rear of the burner 20 at both left and right ends 23 b of the burner main body 23. The outer holding plate 26 is welded. The left and right ends of the ceramic plate 22 are pressed from above by the inner pressing plate 25 and the outer pressing plate 26.
[0028]
On the inner pressing plate 25, a fire transfer plate 25a for performing a fire transfer between the ceramic plates 22 divided in the front-rear direction is formed at an upper portion.
In the central groove of the inner holding plate 25, a ceramic wool extending to the rear of the burner 20 so as to divide the combustion chamber 29 into the left combustion chamber 29L and the right combustion chamber 29R when the burner 20 is housed is divided. The combustion chamber partition bar 27 is fitted from above. A thermal expansion packing 92 having substantially the same shape as the upper surface of the combustion chamber partition bar 27 is placed on the combustion chamber partition bar 27. The components of the thermal expansion packing 92 include vermiculite which expands when heated. When the burner 20 is stored, a gap G is formed between the bottom surface 11 of the oil tank 10 and the thermal expansion packing 92.
[0029]
As shown in FIG. 4, a rail 90 is formed on the side plate 81 of the burner case 80 so as to extend in the front-rear direction on the inside and slide the burner 20 in the front-rear direction. The rail 90 includes a lower rail 90b that supports the flange 20a of the burner 20, and an upper rail 90a that restricts upward movement so that the burner 20 does not hit the bottom surface 11 of the oil tank 10.
[0030]
As shown in FIG. 3, the burner 20 is guided by the rail 90 and stored in the burner case 80 through the front opening 85. At this time, as shown in FIG. 4, the burner case 80 is divided vertically by the burner 20 and the rail 90 to form a combustion chamber 29 formed between the combustion surface of the ceramic plate 22 and the bottom surface 11 of the oil tank 10. And a lower chamber 88 (non-combustion chamber) formed between the bottom surface 23g of the burner main body 23 and the lower plate 82 of the burner case 80.
[0031]
As shown in FIGS. 1 and 4, a throat 28 including a throat upper plate 28a and a throat lower plate 28b extending from the front surface of the burner main body 23 to the center of the mixing chamber 21 is provided in the burner main body 23. Then, the fuel gas and the combustion air are guided to the center of the burner 20 while being mixed.
[0032]
As shown in FIGS. 1 and 2, an exhaust passage 30 that guides the combustion gas from the burner 20 to the outside of the body communicates with a combustion chamber 29 provided at a lower front portion of the oil tank 10 and is provided on the left and right outer sides of the oil tank 10. A passage 31L, a right passage 31R (collectively, left and right passages 31), a rear passage 32 that communicates with the left and right passages 31 and is provided behind the oil tank 10, and a vertically extending exhaust duct that communicates with the rear passage 32 and has an open top. 33.
[0033]
As shown in FIG. 2, the left and right passages 31 are formed by a space surrounded by the side plates 81 and the rear plate 84 and the left and right side surfaces 15 and 16 of the oil tank 10. In the left and right passages 31, side fins 41 having a U-shaped cross section are welded to the left and right side surfaces 15, 16 in horizontal contact with each other vertically.
[0034]
On the other hand, the rear passage 32 is formed by a space surrounded by the rear surface portion 14 of the oil tank 10 and the rear plate 84, as shown in FIGS. Inside the rear passage 32, the rear surface portion 14 is provided with a row on each of the left and right sides and an inclined rear fin 42 a having a U-shaped cross section which is arranged in parallel in parallel with being inclined upward to the center side, and a side surface portion 15 of the oil tank 10. 16 and the fins 42b immediately after the lead having a U-shaped cross section extending in the vertical direction are welded in a surface contact with each other.
These fins 41 and 42 promote heat exchange between the combustion gas and the cooking oil.
[0035]
Since the exhaust passage 30 is formed so as to surround the periphery of the oil tank 10 as described above, a heat receiving area from the combustion gas is increased, the thermal efficiency is increased, and energy is saved.
As a result, the cooking oil can be sufficiently heated by providing the burner 20 only at one place, and a plurality of burner units are not required, so that the manufacturing cost can be reduced.
[0036]
Since the side fins 41 and the oblique rear fins 42a are provided on the side surfaces 15, 16 and the rear surface 14, the rising high-temperature combustion gas is guided to the rear passage 32 and the heat receiving surfaces of the fins 41, 42 are provided. The whole can be reliably contacted. As a result, heat exchange between the combustion gas and the cooking oil is greatly promoted, and the thermal efficiency is improved.
Further, since the left and right passages 31 are formed below the step portions 15a and 16a of the left and right side portions 15 and 16 of the oil tank 10, they do not protrude from the width of the upper part of the oil tank 10, and the apparatus is compact.
[0037]
Next, the front plate 83 of the burner case 80 and components around the front plate 83 will be described.
As shown in FIG. 1, the upper portion 83 a of the front plate 83 of the burner case 80 extends further upward than the side plate 81 and is formed at a predetermined interval from the front inclined portion 13 a of the front portion 13 of the oil tank 10.
On the other hand, as shown in FIG. 5, the lower portion of the front plate 83 is formed by bending the front plate 83 so as to be perpendicular to the burner port surface 22a of the burner 20 inclined downward rearward, that is, inclined upward rearward. Is done.
[0038]
The lower portion of the front plate 83 is formed as an insertion surface portion 83c into which the ignition electrode rod 51 and the frame rod 52 (FIG. 14) are inserted in parallel with the flame port surface 22a of the burner 20 by screwing. As shown in FIG. 14, a rectangular play insertion hole 83d (center side) larger than the first fixing member 48 for loosely inserting the ignition electrode rod 51 and the frame rod 52 together with a first fixing member 48 described later. 83e (left and right outer sides) are respectively formed. That is, the ignition electrode rod 51 is inserted to the center side, and the frame rod 52 is inserted to the left and right outer sides.
Further, a rectangular ignition confirmation window 50 for confirming ignition of the burner 20 and a circular insertion hole 83b for inserting a mixing tube 74 described later are formed in the insertion surface portion 83c.
[0039]
On the upper surface of the front end 23c of the burner main body 23, as shown in FIGS. 11 and 14, fixtures 40 for positioning the ignition electrode rod 51 and the frame rod 52 by fixing them respectively to the burner 20 are provided. The fixing tool 40 includes a first fixing member 48 for inserting the rods 51 and 52, a second fixing member 49 for fixing the first fixing member 48 to the burner 20, and a retainer for covering the rods 51 and 52 from the near side. And a plate 94.
[0040]
The first fixing member 48 is formed by bending a single plate into a U-shape, and has a vertical surface portion 48c formed with a circular positioning hole 48a for positioning the rods 51 and 52 by inserting the rods 51 and 52, respectively, and an ignition electrode rod. It comprises 51 spark target portions 48b and a connecting portion 48d for connecting them.
[0041]
On the other hand, the second fixing member 49 is a plate member having an L-shaped cross section provided with a horizontal surface portion 49a and a vertical surface portion 49b. The horizontal surface portion 49a is fixed to the upper surface of the front end portion 23c with screws from above, and The vertical portion 48c of the first fixing member 48 is fixed by screws 99 from the front by the surface portion 49b.
Flanges 51a are formed on the rods 51 and 52, respectively, and the pressing plate 94 is screwed from the front with the flange 51a pressed against the vertical surface portion 48c of the first fixing member 48 from the near side.
[0042]
Further, the insertion surface portion 83c of the front plate 83 is provided with a lid 95 (FIG. 15) that covers both the play insertion holes 83d and 83e from the outside when viewed from the front, and the lid 95 is viewed from the side. It is a plate material that has been drawn in a substantially trapezoidal shape.
The flat mounting surface portion 95d, which is the outer peripheral portion of the lid 95, is tightened at the upper portion with a nut and the lower portion at the front end portion 23c of the burner main body 23 via an annular graphite packing 96 provided on the back side of the mounting surface portion 95d. And screwed together. The lid 95 has lid insertion holes 95a and 95b for loosely inserting the ignition electrode rod 51 and the frame rod 52, and a rectangular outer window 95c facing the ignition confirmation window 50 of the front plate 83. It is formed. Inside the lid 95, a single ceramic wool heat insulating material 86c that covers each pressing plate 94 is provided.
[0043]
The lid 95 is provided with a brass substantially cylindrical sealing joint 45 which fills the gap between the lid play insertion holes 95a, 95b and the rods 51, 52, and a screw hole 95e of the lid 95 is provided by a screw 97. Fixed at. A fastening hole 45b through which the screw 97 is loosely inserted is formed in the sealing joint 45 larger than the screw hole 95e, so that the positions of the rods 51 and 52 fixed to the burner main body 23 are not restricted by the sealing joint 45. It is configured.
A rod insertion hole 45a through which the rods 51 and 52 are inserted is formed in the sealing joint 45, and an O-ring 47 that fills a gap between the rods 51 and 52 is inserted into the inner peripheral surface of the rod insertion hole 45a. In addition, a flat annular graphite packing 46 that fills a gap with the lid 95 is fitted into the contact surface of the sealing joint 45 with the lid 95.
[0044]
FIG. 17 is a cross-sectional view of a side view of a part of a fryer filed by the applicant in advance, in which an ignition electrode rod 251 and a frame rod (not shown) are inserted through an insertion hole 283d of a front plate 283 to form a flange. 251 a shows a state where the target plate 248 of the ignition electrode rod 251 is fixed to the burner 220 while being fixed to the front plate 283.
In this fryer, an exhaust leakage prevention plate 245 made of ceramic wool is sandwiched between each flange 251a and the front plate 283 to prevent the combustion exhaust in the combustion chamber 229 from leaking from the insertion hole 283d.
However, since the exhaust leak prevention plate 245 is made of ceramic wool and its thickness is easily changed, the position of the tip of the rod is easily shifted. In addition, since many components are interposed between the burner 220 and the front plate 283, dimensional errors are accumulated and these positions are likely to shift, and the positional relationship between the rod fixed to the front plate 283 and the burner 220 is increased. Is shifted. However, since the rod is fixed to the front plate 283, the displacement cannot be adjusted, and there is a possibility that ignition failure or erroneous detection of the flame state may occur.
[0045]
On the other hand, in the flyer 1 of the present embodiment, as shown in FIG. 14, the play insertion holes 83d and 83e of the insertion surface portion 83c of the burner case 80 are formed larger than the first fixing member 48, and the lid is Since the lid play insertion holes 95a and 95b of the body 95 are formed larger than the ignition electrode rod 51 and the frame rod 52, the rods 51 and 52 are provided with the play insertion holes 83d and 83e and the cover play insertion holes 95a and 95a, respectively. The positioning is performed by the fixture 40 fixed to the burner 20 without being positioned by the 95b.
As a result, even if there is some dimensional error between the front plate 83, which is the wall surface of the combustion chamber 29, and the burner 20, and they are shifted from their normal positions, the positional relationship between the ignition electrode rod 51 and the burner 20, and the flame The positional relationship between the rod 52 and the burner 20 does not shift.
[0046]
In the present embodiment, various gaps are formed in order to make the positional relationship accurate. However, leakage of the combustion gas is prevented by the following seal structure.
That is, the gap formed between the rod insertion hole 45a and the ignition electrode rod 51 or the frame rod 52 is sealed by the O-ring 47, and the gap is formed between the lid play insertion holes 95a and 95b and the sealing joint 45. The gap formed is sealed with the graphite packing 46, and the gap between the loose insertion holes 83 d and 83 e of the insertion surface portion 83 c and the mounting surface portion 95 d of the lid 95 is further sealed with the graphite packing 96.
As a result, the ignition electrode rod 51 and the frame rod 52 can be accurately positioned with respect to the burner 20 without exhaust leakage. Therefore, ignition performance and flame detection accuracy are improved.
[0047]
If the ignition electrode rod 51 and the frame rod 52 need to be repaired while the fryer 1 has been used for a long time, the door 2a (FIG. 1) provided on the front of the main body case 2 is first opened.
Next, after removing the screw 97 of the sealing joint 45 and pulling out the sealing joint 45 from each of the rods 51 and 52, the lid 95 and the front heat insulating material 86c inside the lid 95 are removed.
Then, a screw 99 for fixing the first fixing member 48 and the second fixing member 49 for positioning the rod to be repaired is removed from the front, and the first fixing member 48 is attached to the front plate 83 with the rod attached. From the loose insertion hole (83d or 83e).
[0048]
As described above, the rods 51 and 52 can be easily attached to and detached from the burner 20 without removing the front plate 83 from the burner case 80 and without removing the entire burner 20 from the appliance, thereby facilitating maintenance work.
Further, since the rod can be taken out of the instrument without removing the rod from the first fixing member 48, when inspecting the ignition electrode rod 51, the positional relationship with the target portion 48b is maintained without breaking the positional relationship with the target portion 48b. Can be fixed to the burner 20 again.
[0049]
Further, since the O-ring 47 has a circular cross section, it is possible to adjust the displacement of the rods 51 and 52 in the insertion direction, and it is possible to further improve ignition performance and flame detection accuracy.
On the other hand, the graphite packings 46 and 96 provided between the sealing joint 45 and the lid 95 and between the lid 95 and the insertion surface 83c serving as the combustion chamber wall surface have heat resistance, so that the insertion surface 83c and the lid are not heat-resistant. Even if the body 95 becomes hot, it does not thermally deform. Therefore, there is no gap due to thermal deformation, and it is possible to reliably prevent exhaust leakage.
In addition, since the sealing material of the graphite packings 46 and 96 and the O-ring 47 is not brittle like ceramic wool, the shape of the sealing material can be maintained even when the sealing joint 45 and the lid 95 are removed, and the sealing material is repeated many times. Can be used. Therefore, it is not necessary to replace the sealing material every time maintenance is performed.
[0050]
In addition, since the ignition electrode rod 51 and the frame rod 52 are formed of the same component, and the fixture 40 is also formed of the same component, the manufacturing cost can be reduced by sharing the components. Further, since the ignition electrode rod 51 is provided with the identification joint 98 on the frame rod 52, it is possible to easily prevent a wrong connection of a cord connected to the rod.
In addition, at the time of product development, depending on the distribution of the fuel gas in the burner 20, the ignition electrode rod cord is connected to a rod having better ignition performance (for example, to the right rod) and used as an ignition electrode rod. Since the flame rod can be connected to a rod having good flame detection performance and used as a frame rod, the ignition electrode rod, the frame rod, and the fixture do not need to be detached.
[0051]
Further, as shown in FIG. 3, the ignition confirmation window 50 is formed on the insertion surface portion 83c which is inclined upward and rearward, so that the maintenance worker can determine whether the ignition state or the flame state is higher than the ignition confirmation window 50. 1 can be seen obliquely downward (arrows in FIG. 1), and can be confirmed well without being in a low posture.
[0052]
In addition, the operator holds a tool such as a driver in a direction perpendicular to the insertion surface portion 83c in order to maintain the burner 20, the ignition electrode rod 51, and the frame rod 52, but the insertion surface portion 83c is inclined upward and backward. Therefore, the force is easily applied, and the rods 51 and 52 can be easily attached and detached. Further, since the insertion surface portion 83c is easy to see, the work is easy.
In this way, the maintenance work can be performed in an easy posture.
Further, since the insertion surface 83c is formed perpendicular to the flame surface 22a of the burner 20, the rods 51 and 52 can be inserted in a state parallel to the flame surface 22a and perpendicular to the insertion surface 83c. Positioning becomes accurate.
[0053]
Next, the supply unit 70 that supplies fuel gas and combustion air to the left and right burners 20L and 20R will be described.
As shown in FIG. 1, the supply unit 70 includes a fuel gas supply unit 70G, an air supply unit 70A, and a mixing supply unit 70M as a junction of the fuel gas supply unit 70G and the air supply unit 70A. Note that the suffixes of 70G, 70A, and 70M are the initials of GAS, AIR, and MIX.
[0054]
As shown in FIG. 5, the mixing supply unit 70M includes a gas inlet 74a through which fuel gas is introduced from the fuel gas supply unit 70G, and an air inlet 74c through which combustion air is introduced from the air supply unit 70A. , And a U-shaped mixing pipe 74 for sending the air-fuel mixture to the burner 20. On the downstream side of the mixing tube 74, a flange 74b to be screwed to the front plate 83 is formed. The mixing tube 74 is inserted through the insertion hole 83b of the front plate 83 and the inlet 23f of the burner main body 23, and is brought into contact with the throat 28 of the burner 20 to be integrated with the throat 28 as a mixture flow path. is there.
[0055]
As shown in FIGS. 1 and 15, the air supply unit 70 </ b> A includes, from the upstream side, one turbo fan 71, an air supply distributor 89 connected to the ejection port 71 a of the turbo fan 71, and a branch from the air supply distributor 89. And left and right blower tubes 72L, 72R connected to the left and right mixing tubes 74L, 74R, respectively.
The blower tubes 72L, 72R extend substantially parallel to the lower plate 82 of the burner case 80, that is, are formed so as to be inclined downward rearward, and two air supply joints 89a are provided at the upstream end thereof, while the downstream end is provided. Are provided with flexible silicon tubes 73L and 73R. In addition, the turbo fan 71 is disposed at a rear position on the case bottom surface portion 2b serving as the bottom surface of the main body case 2.
[0056]
As shown in FIG. 1, the fuel gas supply unit 70G includes, from the upstream side, a gas control unit 75 provided on the case bottom surface 2b to control the supply and stop of the fuel gas, and an upstream gas pipe , A downstream gas pipe 77.
[0057]
As shown in FIG. 5, a gas nozzle 78 is fitted to the downstream gas pipe 77 at a downstream end thereof so as to face the side surface of the mixing pipe 74, and a flange 77c is formed in the vicinity thereof. An O-ring 114 is fitted on the side. On the other hand, a large-diameter cylindrical portion 77d having an O-ring 112 on the outer periphery is formed at the upstream end of the downstream gas pipe 77.
The downstream gas pipe 77 is connected to the gas inlet 74 a of the mixing pipe 74 by a cap nut 77 a with a flange 77 c in contact with the gas inlet 74 a, and a gap between the gas inlet 74 a and the downstream gas pipe 77 is sealed by an O-ring 114. .
[0058]
The upstream gas pipe 76 has a downstream horizontal portion 76a extending long in the front-rear direction, an upstream vertical portion 76b (FIG. 1), and a large-diameter cylindrical portion 77d of the downstream gas pipe 77 welded to the tip of the horizontal portion 76a. And a threaded tube portion 76c having a larger outer diameter and an outer periphery grooved. By inserting the large-diameter tube portion 77d of the downstream gas tube 77 into the screw tube portion 76c, the downstream gas tube 77 is connected to the upstream gas tube 76 so as to be slidable back and forth. The pipe 76 is prevented from coming off the downstream gas pipe 77.
The threaded tube portion 76c, the large-diameter tube portion 77d, and the O-ring 112 constitute a slide connection portion 110, and the downstream gas pipe 77 is slidably connected to the upstream gas pipe 76 while maintaining the sealing property. I have.
[0059]
In the fryer 1 configured as described above, when the burner 20 needs to be repaired, as shown in FIGS. 1 and 5, after opening the door 2 a of the main body case 2, the screw of the upstream gas pipe 76 is removed. While loosening the cap nut 77b of the downstream gas pipe 77 fitted to the cylindrical portion 76c, removing the screw of the flange 74b of the mixing pipe 74, the mixing pipe 74 integrated with the downstream gas pipe 77 is removed from the silicon tube 73. And remove it from the front plate 83 of the burner case 80.
Then, the front plate 83 is removed from the main body case 2 by removing the screws and nuts. Next, as shown in FIGS. 3 and 4, the flange 20a of the burner 20 is slid on the lower rail 90b, and the burner 20 is moved obliquely upward (on a substantially horizontal plane) from the front opening 85 on the front surface of the burner case 80. To perform repairs such as replacement of the ceramic plate 22.
In this manner, the burner 20 can be easily taken out only by sliding the burner 20 forward. Further, it is not necessary to replace the oil tank 10 with a new oil tank 10 for a failure of the burner 20, and the maintenance cost can be reduced.
Moreover, since it is not necessary to remove the lower plate 82 of the burner case 80, there is no need to loosen the nut from below, and the burner 20 can be easily taken out.
Further, since the inlet portion 23f of the burner main body 23 is formed on the front surface, the mixing pipe 74 can be attached and detached from the front surface, and maintenance of the burner 20 becomes easy.
[0060]
Further, since the burner 20 is slid forward along the rail 90, the burner 20 can be taken in and out with a light force. In addition, the rail 90 makes the positional relationship between the burner 20 and the oil tank 10 accurate, and the food can be cooked by heating the oil tank 10 at an appropriate position.
Further, the burner 20 is an all-primary pneumatic burner, and since there is little restriction on the direction of the combustion surface, the burner 20 can be easily placed in and out of the burner 20 and can be arranged in a position and a direction that can maintain good cooking performance.
[0061]
Generally, in a kitchen such as a fast food restaurant, there is not much space left, right, front and rear of the fryer 1, but since the burner 20 is provided on the bottom surface of the oil tank 10, the vessel can be made compact. In addition, since the cooking oil is heated from below the oil tank 10, the cooking oil flows smoothly, and the food can be cooked uniformly.
Further, since the user pulls out the burner 20 from the front of the container where the cooking operation is performed, it is not necessary to newly provide a space for removing the burner, and the degree of freedom of the installation position of the container is large.
[0062]
Further, when the burner 20 is stored, a gap G is formed between the combustion chamber partition bar 27 and the oil tank bottom portion 11, as shown in FIG. 4, so that the burner 20 can be smoothly taken in and out.
[0063]
Then, when the combustion of the burner 20 is started, the thermal expansion packing 92 is heated and expands to close the gap G, and completely separate the combustion chamber 29 into right and left.
As a result, for example, when cooking is performed only in the left oil tank 10L, all of the combustion gas generated from the left burner 20L passes from the left combustion chamber 29L to the left passage 31L and the left oil passage 10L to the left oil tank 10L. It is discharged from the exhaust duct 33 to the outside of the body while exchanging heat. That is, the high-temperature combustion gas does not leak from the gap G to the adjacent right combustion chamber 29R.
[0064]
Therefore, it is possible to prevent overheating of the empty right oil tank 10R without cooking, and even if cooking oil adheres to the right oil tank 10R, oil smoke is not generated from the right oil tank 10R, and the appliance can be safely used. Can be used.
Moreover, since the combustion gas is not used for heating the right oil tank 10R, and all the combustion gas can be used for heating the left oil tank 10L, the heat efficiency is increased and the economy is increased.
Further, since the combustion chamber 29 is easily partitioned by the combustion chamber partition bar 27 only by storing the burner 20 in the burner case 80, there is no need to provide a burner having left and right independent combustion chambers. Can be suppressed.
[0065]
As shown in FIG. 1, the positional relationship between the burner case 80 and the supply unit 70 fixed to the case bottom surface 2 b is likely to shift in the front-rear direction. Specifically, the center axis of the blower tube 72 fixed to the turbofan 71 and the center axis of the upstream end of the mixing tube 74 are easily shifted.
This is because the oil tank 10 is large and is formed by heat welding, so that the constituent plates are easily welded in a state of being slightly shifted up and down. In this case, the positional relationship between the burner case 80 and the upstream gas pipe 76 and the blower pipe 72 is shifted. Specifically, as shown in FIG. 5, a deviation between the central axis of the horizontal portion 76a of the upstream gas pipe 76 and the central axis of the downstream gas pipe 77 and a deviation in the front-rear direction occur. Similarly, also in the air supply path, the center axis of the blower tube 72 and the center axis of the air inlet 74c of the mixing tube 74 are shifted. FIG. 9 shows a fryer manufactured according to the design dimensions.
[0066]
Therefore, in the fryer 1 of the present embodiment, as shown in FIG. 1, the blower pipe 72 of the air supply unit 70A and the air inlet 74c of the mixing pipe 74 are connected by the silicon tube 73. As can be seen from the comparison of FIG. 9, the silicon tube 73 bends three-dimensionally and absorbs the displacement, so that the ventilation tube 72 can be piped without difficulty. As a result, the blower tube 72 does not break or deform, and can prevent air leakage. In addition, it can be easily implemented with an inexpensive member such as the silicon tube 73.
In particular, since the blower pipe 72 has a large pipe diameter, it cannot be swung like an upstream gas pipe 76 described later, and a configuration for absorbing a displacement in the air supply unit 70A is required, and the blower pipe 72 is bent three-dimensionally. A silicon tube 73 that can be used is suitable.
[0067]
On the other hand, in the fuel gas supply section 70G, since it is necessary to reliably prevent gas leakage, a slide connection section 110 is used instead of the silicon tube as shown in FIG. By moving the downstream gas pipe 77 forward and backward with respect to the upstream gas pipe 76 by the slide connection portion 110, the total length of the upstream gas pipe 76 and the downstream gas pipe 77 is adjusted to absorb a shift in the front-rear direction.
Further, since the horizontal portion 76a of the upstream gas pipe 76 extends long in the front-rear direction as shown in FIGS. 1 and 9, it is possible to swing up, down, left and right with the upper end of the vertical portion 76b as a fulcrum, Accordingly, the slide connection portion 110 at the tip can also move up, down, left, and right. For this reason, the upper, lower, left and right displacements of the upstream gas pipe 76 and the downstream gas pipe 77 can be absorbed to face each other. In this way, the displacement of the fuel gas supply unit 70G can also be three-dimensionally absorbed.
[0068]
As a result, assemblability and maintainability are improved, and gas leakage due to cracks or abnormal deformation of the upstream gas pipe 76, the downstream gas pipe 77, and the mixing pipe 74 can be prevented.
It is also conceivable to divide the mixing pipe 74 serving as the mixing and supplying section 70M without dividing the air supply section 70A and the fuel gas supply section 70G. However, if a silicon tube is connected between them, reliable prevention of gas leakage can be expected. On the other hand, if the connection is made by the slide connection part, the movement is restricted by the air supply part 70A, and the displacement cannot be absorbed three-dimensionally. For this reason, in the present embodiment, the air supply unit 70A and the fuel gas supply unit 70G are divided instead of the mixing supply unit 70M.
[0069]
Next, the arrangement of the left blower tube 72L of the air supply unit 70A will be described.
As shown in FIG. 1, a triangular prism-shaped space S <b> 1 having the lower plate 82 inclined downward and backward is formed below the lower plate 82 of the burner case 80. Using this space S1, a left blower pipe 72L is provided.
[0070]
As shown in FIG. 15, the blower tube 72 has a different shape on the left and right when viewed from the front. The right blower tube 72R extends straight from the air supply distributor 89 to the right silicon tube 73R, whereas the left blower tube 72L is bent at 90 degrees at two places, and an upstream portion 72La extending in parallel with the right blower pipe 72R from the air supply distributor 89 into the space S1 and a left side plate 81 of the burner case 80 in the width direction in the space S1. An intermediate portion 72Lb extending to the vicinity and a downstream portion 72Lc extending in parallel with the right blower tube 72R to the left silicon tube 73L in the space S1.
[0071]
As shown in FIG. 1, a merging box 61b of the filtering device 60 is hung from the lower plate 82 in the vicinity of the blower tube 72, so that an intermediate portion extending left and right of the left blower tube 72L behind the merging box 61b. When the portion 72Lb is disposed, the left blower tube 72L cannot be taken out from the front due to obstruction at the time of maintenance. However, since a space S1 having a triangular cross section when viewed from the side is formed below the burner 20, that space is formed. By utilizing S1, the middle portion 72Lb of the left blower tube 72L can be traversed in the device.
Here, the layout of the blower tube 72 will be described with reference to FIG. FIG. 6A shows the oil tank bottom part 11 inclined backward and downward, and FIG. 6B shows the oil tank bottom part 211 formed horizontally. The space S1 is indicated by a thick broken line in FIG. 6A and hatched in FIG.
[0072]
In the fryer 201 provided with the oil tank 210 having the same volume as the oil tank 10 of FIG. 6A and having the bottom part 211 formed horizontally, the burner 220 is also parallel to the bottom part 211 as shown in FIG. The lower plate 282 of the burner case 280 is also formed horizontally, and the front of the lower plate 282 is lowered.
As a result, if it is attempted to use the left blower tube 272L having the same thickness as the left blower tube 72L in FIG. 6A, the middle portion 272Lb must be arranged at a position lower than the triangular space S1. In order to avoid other parts below S1, it is necessary to bend the left air duct 272L many times, which increases the resistance of the air supply passage.
[0073]
On the other hand, in the fryer 1 of the present embodiment, since the triangular space S1 is formed, the space is not easily restricted by other components, and the blower tubes 72 can be arranged relatively freely. Since the layout is easy as described above, it is not necessary to provide a bent portion in order to avoid an obstacle, and the air supply resistance is reduced and air can be supplied smoothly.
In addition, since the blower tube 72 is housed in the space S1, the layout of other components is facilitated.
In addition, since the blower tube 72 can be arranged close to the high-temperature oil tank 10, the combustion air passing therethrough is sent to the burner 20 by receiving the surrounding heat, thereby increasing the thermal efficiency.
[0074]
Next, the filtering device 60 will be described.
As shown in FIG. 1, the filtering device 60 includes an oil discharging unit 61 that discharges oil from the lower center of the front surface of the oil residue housing unit 12, and an oil that includes a filter 63 a and filters cooking oil discharged from the oil discharging unit 61. A tank 63 and a pump 64 for returning filtered cooking oil to the oil tank 10 via an oil supply pipe 66 are provided. The oil drain unit 61 includes two oil drain pipes 61a connected to the left and right oil residue storage units 12, and a junction box 61b for collecting oil flowing through each of the oil drain pipes 61a at one location. One oil drain port 61c is formed on the bottom surface of the oil tank 63 so as to face the tank inlet 63b of the oil tank 63. The oil drain pipe 61a and the oil feed pipe 66 are provided with an oil drain valve 62 and an oil feed valve 65, respectively. The oil supply pipe 66 and the oil supply valve 65 are arranged at the rear of the device. The pipe axis direction of the refueling pipe 66 in the refueling valve 65 is inclined by 45 degrees with respect to the vertical direction.
The refueling valve 65 is opened and closed via a link lever 67 by operating an operation lever 68 provided on the front of the appliance.
[0075]
The oil supply valve 65 which is opened and closed in this manner is a ball valve, and as shown in FIG. 10, a spherical metal valve body 55 having a cylindrical valve body opening 55a and a seat portion opening 56b. And a resin-made sheet portion 56a.
10 (a) shows a state in which the fuel supply valve 65 is closed, FIG. 10 (c) shows a state in which the valve is completely opened, and FIG. 10 (b) shows a state in which the valve is slightly opened in the middle.
[0076]
As shown in FIGS. 12 and 13, the refueling valve 65 is fixed to the rear end of the link lever 67 and directly rotates the valve body 55 (FIG. 10). And a leaf spring 59 fixed to the valve body lever 57 and rotated along the side surface 58b of the support cylinder 58.
[0077]
The valve body lever 57 is configured to be rotatable from a state parallel to the pipe axis direction of the oil supply pipe 66 to a state perpendicular thereto, and has a link mounting portion 57 a parallel to the upper surface portion 58 a of the support cylinder 58, and a support cylinder 58. And a spring mounting portion 57b opposed to the side surface portion 58b.
A front projection 58c and a rear projection 58d are formed on the side surface 58b of the support cylinder 58 so as to project forward and backward, respectively.
The leaf spring 59 has a fixed portion 59a fixed to the spring attachment portion 57b of the valve body lever 57, and a front engagement extending back and forth from the fixed portion 59a and capable of engaging with the respective projections 58c and 58d by rotation. And a rear engaging portion 59d. However, the front and rear engaging portions 59c and 59d do not engage at the same time.
[0078]
At the normal time when oil is not supplied from the oil tank 63 to the oil tank 10, that is, when the oil supply valve 65 is closed, as shown in FIG. 1, the operation lever 68 is in a vertical state, and is connected to the operation lever 68 by the link lever 67. As shown in FIG. 12, the valve body lever 57 thus turned faces rearward and downward (solid line in FIG. 1). At this time, the front engagement portion 59c of the leaf spring 59 fixed to the valve body lever 57 is engaged with the front projection 58c. On the other hand, the rear engagement portion 59d is not engaged with the rear projection 58d of the support cylinder 58.
Therefore, at normal times, since the rotation start resistance of the valve body lever 57 is increased by the engagement between the front engagement portion 59c and the front projection 58c, the refueling valve 65 is caused by the weight of the link lever 67 and the operation lever 68. It doesn't open without you knowing it.
[0079]
In particular, immediately after the cooking oil is filtered and returned to the oil tank 10, the metal valve body 55 and the resin sheet portion 56a are heated by the high-temperature cooking oil that has passed through the oil supply valve 65, and the thermal expansion thereof occurs. Due to the difference in the coefficient, the seat portion 56a expands more than the valve body 55 to form a gap, or the cooking oil acts like a lubricating oil to reduce the sliding resistance, so that the valve closing holding force decreases. Although it is easy, since the valve body lever 57 is engaged, the valve body 55 does not tilt as shown in FIG. 10 (b), and it is possible to prevent the fuel supply valve 65 from being opened by its own weight.
[0080]
As a result, the cooking oil in the oil tank 10 does not flow back to the oil tank 63 through the oil supply valve 65 after the filtration operation is completed.
Therefore, even if the valve body opening 55a and the seat opening 56b are formed large with respect to the valve body 55, the cooking oil does not leak, so that the flow rate of returning the filtered oil to the oil tank 10 can be increased and the return time of the filtered oil can be shortened. .
[0081]
On the other hand, when returning the filtered oil to the oil tank 10, the operation lever 68 is opened to rotate the valve body lever 57 forward through the link lever 67 as shown in FIG. 13 (broken line in FIG. 1). Then, the front engaging portion 59c of the leaf spring 59 is moved over the front protruding portion 58c of the support cylinder 58 to be removed, and the rear engaging portion 59d is engaged with the rear protruding portion 58d.
During the operation of the pump 64, the rear engagement portion 59d is engaged with the rear projection 58d, so that the oil supply valve 65 is closed without permission and the oil supply from the oil tank 63 to the oil tank 10 is interrupted. There is no problem that the oil supply time is reduced and the refueling time is lengthened.
In this manner, with a simple configuration of engagement / disengagement between the leaf spring 59 and the support cylinder 58, it is possible to prevent leakage of cooking oil, interruption of refueling, or prolongation of refueling time, and keep production costs low.
Further, the operator does not need to constantly monitor the turning position of the operation lever 68 (that is, the open / close state of the fuel supply valve 65) in order to grasp the occurrence of such a problem, so that the worker can concentrate on other work without worry. .
[0082]
Next, the turbo fan 71 of the supply unit 70 will be described.
In general, as shown in FIG. 1, the casing of the fan has a distance <a <b <c <d <e from the rotation shaft, and the distance increases from the downstream side of the air flow path.
In the turbo fan 71, the ejection direction of the turbo fan 71 is inclined more than the vertical direction so that the ejection port 71a (the portion having the largest distance from the rotation axis) is located almost directly above the rotation axis. Therefore, the ejection port 71a is disposed near the center of gravity axis GF of the turbo fan 71. Further, the depth dimension W required for installing the turbofan 71 is small.
[0083]
The turbo fan 71 has an impeller formed to face backward with respect to the blowing direction, and has a characteristic that a change in air volume is small with respect to a change in wind pressure. On the other hand, in the sirocco fan (multi-blade fan) conventionally used, the impeller is formed to face forward, and the change of the air volume is large with respect to the fluctuation of the wind pressure.
[0084]
For this reason, in the fryer 1 employing the turbo fan 71, even if a strong wind blows toward the outlet of the exhaust duct 33, the exhaust pressure at this outlet is maintained high and overcomes the wind pressure. There is no backflow.
Moreover, in the case of the same airflow, the pressure difference between the inlet and the outlet of the turbo fan is considerably larger than that of the sirocco fan, so that the combustion air can be sufficiently sucked.
[0085]
Therefore, it is possible to prevent poor ignition or poor combustion due to backflow of outside air or insufficient air supply, so that the user can safely use the appliance and no trouble such as stopping during operation.
In addition, with a turbofan, there is no need to create a large differential pressure due to an increase in the number of revolutions of the fan, and noise from equipment can be suppressed.
[0086]
Furthermore, the turbo fan 71 has a larger interval between the blades, a longer blade width, and a smaller curvature of the blades than the sirocco fan. As a result, the fan blowing performance can be maintained at a high level over a long period of time, and the durability is improved.
[0087]
In the fryer 1, the installation space for the turbofan 71 is not so much in the horizontal direction due to the gas control unit 75 and the pump 64 of the filtration device 60, but the turbofan 71 is arranged so that its jetting direction is inclined from the vertical direction. The depth dimension W required for the installation can be reduced, and it can be arranged in a narrow place.
[0088]
As described above, since the depth dimension W of the turbofan 71 is reduced, other parts can be laid out using the space created around the turbofan 71.
Further, even if the uppermost part of the gas control unit 75 is located at a high position, the turbo fan 71 is arranged obliquely, so that the blower pipe 72 can be arranged avoiding the gas control unit 75.
[0089]
In addition, the turbo fan 71 can be installed at an optimum position such as a position where oil smoke is difficult to be sucked (that is, a lower rear portion away from the tank inlet 63b of the oil tank 10 or the oil tank 63).
Since the turbo fan 71 is less likely to be clogged with dust, it is not necessary to frequently perform maintenance for removing dust from the fan, which is convenient. As a result, the fan can be arranged on the far side (a place where the amount of smoke is small) in the appliance far from the door 2a in front of the appliance and the maintenance work is very troublesome. Can be prevented.
[0090]
Since the turbo fan 71 is provided at the lower rear part of the apparatus, the length of the blower pipe 72 connecting the mixing pipe 74 connected to the upper burner 20 and the lower turbo fan 71 increases, and there is a concern that the flow path resistance increases. Actually, since the ejection direction of the turbo fan 71 is directed toward the inlet 23f of the burner main body 23 in front, the blower tube 72 can be formed straight when viewed from the side, and the flow path resistance decreases. The air supply efficiency is improved. That is, the flow rate of air supplied to the burner 20 increases for a predetermined capacity of the fan.
[0091]
Further, since the ejection port 71a of the turbo fan 71 is located near the center of gravity axis GF of the turbo fan 71, the center of gravity GD of a relatively heavy component such as the air supply distributor 89 or the air supply joint 89a approaches the center of gravity axis GF. As a result, the load is not unevenly applied due to such own weight, and the turbo fan 71 is stabilized.
[0092]
Next, exhaust blockage detection will be described.
The exhaust duct 33 may be blocked by some foreign matter.
On the other hand, when the burner 20 is blocked, the turbo fan 71 sucks oil smoke generated from the oil tank 10 and floating around the apparatus or oil smoke coming out of the oil tank 63 together with combustion air and dust, and the oil is removed. This occurs when dust adheres to the inside of the burner 20 and becomes clogged with dust.
[0093]
In order to detect such an exhaust blockage, as shown in FIG. 8, two fan detection conduits 35 are connected to the ejection port 71 a of the turbo fan 71, while being connected to the blower pipes 72 </ b> L and 72 </ b> R of the supply unit 70. Are connected to burner inspection conduits 36L and 36R, respectively, and differential pressure switches 34L and 34R are connected to tips of these inspection conduits 35 and 36, respectively.
The differential pressure switches 34L, 34R have their cases divided by a diaphragm 34La, 34Ra into a primary chamber 34p and a secondary chamber 34s, and the primary chamber 34p is connected to burner test tubes 36L, 36R. The fan detection conduit 35 is connected to 34s. Microswitches 34Lb and 34Rb that are turned on and off by deformation of the diaphragms 34La and 34Ra are provided above the primary chamber 34p.
[0094]
For example, when the exhaust gas is not blocked, the internal pressure in the burner test conduits 36L and 36R becomes lower than the internal pressure in the fan test conduit 35, and the differential pressure between the internal pressure of the primary chamber 34p and the internal pressure of the secondary chamber 34s. Is greater than or equal to a predetermined value, the diaphragms 34La and 34Ra are deformed, and the micro switches 34Lb and 34Rb are pressed to turn on the differential pressure switches 34L and 34R.
On the other hand, when the flame opening of the right burner 20R starts to be clogged, the internal pressure in the right burner test conduit 36R and the internal pressure in the fan test conduit 35 become substantially equal (these differential pressures become less than a predetermined value), and the right diaphragm 34Ra returns to the original shape and the right micro switch 34Rb is no longer pressed, and the differential pressure switch 34R is turned off. When the left burner 20L is closed, the differential pressure switch 34L is turned off. When both the left and right burners 20L and 20R are closed or when the exhaust duct 33 is closed, both the left and right differential pressure switches 34L and 34R are turned off.
[0095]
FIG. 16 is a flowchart of blockage detection control performed by the controller 100 using the differential pressure switch 34.
When the rotation speed of the turbo fan 71 becomes 80% or more of the target rotation speed, the controller 100 first reads signals from the differential pressure switches 34L and 34R (shown as SW1 and SW2 in FIG. 16) (S1).
If both SW1 and SW2 are on, it is determined that the burner 20 and the supply / exhaust passage are not blocked, and the process returns to step 1 to repeat the blockage detection control.
If at least one of SW1 and SW2 is off, an abnormality is determined according to the on / off state of SW1 and SW2, and the process proceeds to steps 4 to 6 (S3).
[0096]
In step 3, when SW1 is off and SW2 is on, it is determined that the left burner 20L is closed, and an error code indicating that the left burner 20L is closed is displayed on a display (not shown) of the controller 100 and An alarm (not shown) is sounded (S4), and supply of fuel gas to the left burner 20L is stopped (S7).
[0097]
On the other hand, when SW1 is on and SW2 is off, it is determined that the right burner 20R is closed, an error code indicating that the right burner 20R is closed is displayed, and an alarm is sounded (S5). The supply of the fuel gas to the burner 20R is stopped (S7).
[0098]
When both SW1 and SW2 are off, it is determined that the exhaust duct 33 or both the left and right burners 20L and 20R are closed, an error code indicating the blockage of the exhaust passage is displayed, and an alarm is sounded. (S6) The supply of the fuel gas to both left and right burners 20L and 20R is stopped (S7).
[0099]
According to the blockage detection control process, even when one of the burners is closed, the controller 100 individually grasps the degree of clogging of the left and right burners 20L and 20R, and notifies the error code to that effect. , The burner who needs maintenance can be notified. In other words, the cause of the blockage can be determined from the error code, and inspection of components not related to the blockage (for example, if an error code indicating the blockage of the right burner 20R is displayed, the inspection of the left burner 20L and the exhaust duct 33) can be omitted. , Maintenance work time is reduced.
[0100]
If the controller 100 determines that at least one of the left and right burners 20L and 20R and the supply / exhaust passage thereof is closed, the controller 100 does not supply the fuel gas to the burner 20 determined to be closed, so that the combustion is not performed. Failure can be prevented.
When it is determined that only one burner 20 (for example, the right burner 20R) is closed, the combustion of the non-blocked burner (the left burner 20L) can be continued. Therefore, cooking can be performed in one oil tank (left oil tank 10L) without waiting for repair of the closed burner (right burner 20R).
In this manner, the determination of the closing of each burner 20 can be easily performed only by determining the signal from each differential pressure switch 34.
Further, since the blockage of the burner 20 is detected in this manner, an all-primary pneumatic plate burner that easily causes clogging of the flame port can be used with security, and the advantage that the combustion surface can be freely arranged can be utilized.
In addition, since the wind pressure at the ejection port 71a of the turbo fan 71 is higher than that of a sirocco fan conventionally used for the same blowing rate, a large differential pressure is obtained, and the accuracy of blockage detection is increased.
[0101]
Next, the heat insulation structure of the device will be described.
As shown in FIGS. 1 and 2, an outer heat insulating material 86b made of ceramic wool is provided between the burner case 80 and the oil tank 10 over the entire circumference, as shown in FIGS. In addition, a metal heat-resistant plate 91 is provided on the rear surface portion 14 so as to cover the rear outer heat insulating material 86b in surface contact. On the other hand, between the left and right side portions 15, 16 and the left and right outer heat insulators 86b, below the step portions 15a, 16a of the left and right side portions 15, 16, an inner heat insulator 86a also made of ceramic wool (FIG. 9) (A hatched portion within a thick broken line), and a metal heat-resistant plate 93 that covers and contacts the lower surface and the inner side surface of the inner heat insulating material 86a. A rectifying plate 39 having an L-shaped cross section is screwed to the inner side surface of the heat-resistant plate 93, and one end of the rectifying plate 39 is in line contact with the left and right side surfaces 15 and 16.
[0102]
The combustion gas generated from the burner 20 passes through the exhaust passage 30 when being discharged from the combustion chamber 29 to the outside of the body, and is heat-exchanged with the fins 41 and 42 and the wall surface of the oil tank 10 while being rectified by the rectification plate 39 to form the oil tank. Heat the cooking oil in 10. Although the exhaust gas passage 30 is heated by the passage of the combustion gas, the heat transfer to the outer wall of the main body case 2 is suppressed by the inner heat insulator 86a and the outer heat insulator 86b.
Further, since the inner heat insulating material 86a and the outer heat insulating material 86b are respectively covered by the heat-resistant plates 93 and 91, they are not directly heated by the combustion gas and do not become brittle enough to be separated. Even if it is deteriorated and easily peeled off, the fragments are not covered with the heat-resistant plates 93 and 91 and flow through the exhaust passage 30 to be discharged outside the body. Further, since the inner heat insulating material 86a and the outer heat insulating material 86b do not fall, there is no obstacle in the exhaust passage 30.
Therefore, exhaust resistance does not increase, and poor combustion hardly occurs, which is safe.
[0103]
By the way, since the exhaust passage 30 is made narrow in order to promote heat transfer from the combustion gas to the exhaust passage wall surface, the exhaust passage resistance is generated by peeling or falling of the inner heat insulating material 86a and the outer heat insulating material 86b. However, since these are prevented by the heat-resistant plates 93 and 91, an increase in exhaust resistance can be prevented while maintaining high thermal efficiency.
[0104]
Next, a configuration for protecting the temperature sensor will be described.
As shown in FIGS. 1 and 7, a temperature sensor 53 for detecting the temperature of the cooking oil in the oil tank 10 is provided on the front surface 13 of each of the oil tanks 10L and 10R. The rings 54 are welded respectively.
In each oil tank 10, a bottom net 44 formed by welding a plurality of metal round bars is provided. The bottom net 44 includes a flat mounting portion 44a that supports the basket 43, and a guard portion 44b that is formed at the front center of the mounting portion 44a so as to be inclined upward and forward.
The mounting portion 44a is supported by steps 15a and 16a formed on the left side surface portion 15 and the right side surface portion 16 of the oil tank 10, and left and right bottom net supports 10b provided on the oil tank dividing plate 10a.
On the other hand, the guard portion 44b extends to the front surface portion 13 of the oil tank 10 above the protection ring 54, and has a U-shape that is wider than the protection ring 54 when viewed from above.
[0105]
As described above, the guard portion 44b extending from the mounting portion 44a of the bottom net 44 is disposed above the temperature sensor 53 so as to be inclined upward and forward to the front surface portion 13 of the oil tank 10. Even if 43 is sinked casually, the basket 43 slides on the guard portion 44b and is guided to a predetermined position of the bottom net 44. Therefore, it is not necessary to pay attention so that the basket 43 does not catch on the guard portion 44b, and the usability is good.
In this way, the ingredients can always be cooked uniformly in order to arrange the basket 43 at the correct position.
[0106]
Further, even if the basket 243 is dropped so that the basket 243 hits the guard portion 44b every time the food is thrown in and the guard portion 44b is gradually deformed, the temperature sensor 53 can be easily replaced by simply replacing the bottom net 44 with a new one. The protection function can be maintained.
[0107]
In addition, even if the bottom net 44 is removed when the oil tank 10 is cleaned, the protection tool 54 can prevent the cleaning tool from hitting the temperature sensor 53. In this way, the temperature sensor 53 is protected both during cooking and during cleaning.
Further, since the guard portion 44b extends upward from the mounting portion 44a and is formed like a handle, the bottom net 44 can be easily taken out of the oil tank 10 by holding the guard portion 44b.
[0108]
Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments at all, and it is needless to say that the present invention can be implemented in various modes without departing from the gist of the present invention.
For example, the connection position of the fan detection conduit 35 may be replaced with the air supply distributor 89 instead of the ejection port 71a of the turbo fan 71.
Note that the common air supply passage of the present invention corresponds to the air supply distributor 89, the branch air supply passage corresponds to the blower tubes 72L and 72R and the mixing tube 74, and the differential pressure detecting means corresponds to the differential pressure switches 34L and 34R. .
[0109]
【The invention's effect】
As described in detail above, according to the fryer of claim 1 of the present invention, even if the burner starts to be clogged with oil smoke or dust sucked from the fan, the differential pressure between the pressure on the fan side and the pressure on the burner side is determined for each burner. Since detection is performed, incomplete combustion can be prevented according to the degree of clogging of each burner. Moreover, the detection of clogging of the burner can be performed with a simple configuration of the differential pressure detecting means, and the manufacturing cost can be reduced.
[0110]
Further, according to the fryer of the second aspect of the present invention, the incomplete combustion prevention control is performed by detecting the blockage of the burner. Can be freely arranged.
[0111]
Furthermore, according to the fryer of the third aspect of the present invention, since a turbo fan having a high wind pressure is used for the same air flow rate, a large differential pressure is obtained by the differential pressure detecting means, and the accuracy of blockage detection is improved.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a fryer as one embodiment as viewed from a side.
FIG. 2 is a cross-sectional view of a fryer as one embodiment as viewed from the front.
FIG. 3 is an exploded perspective view of a part of the fryer as one embodiment.
FIG. 4 is a sectional view of a burner as one embodiment and components around the burner as viewed from the front.
FIG. 5 is a cross-sectional view of a part of a fryer according to an embodiment as viewed from a side.
FIG. 6 is an explanatory view of a part of the fryer as viewed from a side.
FIG. 7 is a cross-sectional view of an oil tank on which a bottom net of a fryer is mounted as one embodiment when viewed from above.
FIG. 8 is a schematic explanatory diagram of a fryer as one embodiment.
FIG. 9 is a cross-sectional view of a fryer as one embodiment as viewed from a side.
FIG. 10 is a cross-sectional view of a fuel supply valve as one embodiment as viewed from a side.
FIG. 11 is a sectional view of an ignition electrode rod of a fryer according to an embodiment and components around the ignition electrode rod as viewed from a side.
FIG. 12 is a perspective view of the fuel supply valve as one embodiment when the valve is closed.
FIG. 13 is a perspective view of the fuel supply valve as one embodiment when the valve is opened.
FIG. 14 is an exploded perspective view of a part of a fryer as one embodiment.
FIG. 15 is a cross-sectional view of a fryer as one embodiment as viewed from the front.
FIG. 16 is a flowchart of fryer blockage detection control as one embodiment.
FIG. 17 is a cross-sectional view of a part of a conventional flyer as viewed from the side.
FIG. 18 is a schematic explanatory view of a fryer as a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Fryer, 2 ... Body case, 2b ... Case bottom part, 10 ... Oil tank, 11 ... Bottom part, 20 ... Burner, 20a ... Flange, 22 ... Ceramic plate, 23 ... Burner main body, 27 ... Combustion chamber partition bar, 29 ... combustion chamber, 30 ... exhaust passage, 31 ... left and right passages, 34L, 34R ... differential pressure switch, 35 ... fan inspection conduit, 36 ... burner inspection conduit, 40 ... fixture, 41 ... side fin, 42 ... rear part Fins, 43 basket, 44 bottom mesh, 44a mounting portion, 44b guard portion, 45 sealing joint, 45b fastening hole, 46, 96 graphite packing, 47, 112, 114 O-ring, 48 1st fixing member, 48a ... target part, 49 ... 2nd fixing member, 50 ... ignition confirmation window, 51 ... ignition electrode rod, 52 ... frame rod, 53 ... temperature sensor, 54 ... protective ring, 5 ... Valve element, 57 ... Valve lever, 58 ... Support cylinder body, 58c, 58d ... Front and back projection, 59 ... Leaf spring, 59c and 59d ... Front and back engagement part, 60 ... Filtering device, 65 ... Oil valve, 66 ... Oil supply pipe, 67 ... Link lever, 68 ... Operation lever, 70 ... Supply part, 71 ... Turbo fan, 71a ... Injection port, 72L, 72R ... Blast pipe, 73 ... Silicon tube, 76 ... Upstream gas pipe, 77 ... Downstream gas Pipe, 77b: Cap nut, 80: Burner case, 82: Lower plate, 83: Front plate, 83c: Insert surface, 83d, 83e: Free insertion hole, 85: Front opening, 90: Rail, 92: Thermal expansion packing , 95: lid, 95a, 95b: lid play insertion hole, 95c: outer window, 97: screw, 100: controller, 110: slide connection part, G: gap, S1: space.

Claims (3)

An oil tank filled with cooking oil, a plurality of burners for independently heating the cooking oil in the oil tank, a common fan for supplying combustion air to each of the plurality of burners, and an outlet of the fan. A single common air supply path and a plurality of branch air supply paths branched from the common air supply path and connected to each burner,
Differential pressure detecting means for detecting a differential pressure between the internal pressure of the common air supply path or the fan outlet and the internal pressure of the branch air supply path is provided in each of the branch air supply paths,
A fryer characterized by performing incomplete combustion prevention control according to the detected differential pressure. The fryer according to claim 1, wherein an all-primary pneumatic plate burner having a plurality of flame ports formed on a plane is used as the burner. 3. The fryer according to claim 1, wherein a turbo fan is used as the fan.

Images