Detailed Description
In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.
In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.
Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.
In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.
In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.
It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.
Referring to fig. 1, which is a schematic structural diagram of a weighing type chestnut frying machine 10 according to an embodiment of the present invention, the weighing type chestnut frying machine 10 includes a machine body 100, a frying tool 200, a filtering member 300, a collecting box 400 and a recovering member 500. The frying tool 200 and the filter 300 are respectively connected to the machine body 100. The collection container 400 and the recovery container 500 are respectively connected to the filter 300.
For example, the machine body 100 is used for connecting the frying tool 200, the filtering member 300, the collecting box 400 and the recovering member 500, and has a certain height to provide corresponding working spaces for the frying tool 200, the filtering member 300, the collecting box 400 and the recovering member 500, so that the work among the respective parts is normally ordered.
For example, the fryer 200 is used to fry chestnut to be fried. The chestnuts to be fried include chestnuts to be processed by the weighing type chestnut frying machine of the embodiment. The frying tool 200 is used for processing the Chinese chestnut to be fried into edible Chinese chestnut.
It will be appreciated that the chestnuts to be fried may be initially processed prior to processing using the fryer 200, for example, by first cleaning the shells of the chestnuts to remove the contaminants from the shells, thereby improving the direct eating qualities of the chestnuts that are processed by the weighted chestnut machine of this embodiment.
For example, the filter member 300 serves to transfer the roasted chestnuts discharged from the fryer 200 and to filter out sugar, salt and sand discharged along with the roasted chestnuts, thereby reducing the roasting auxiliary materials in the roasted chestnuts.
For example, the collection container 400 is used to receive the roasted chestnuts transferred from the filter 300, that is, the roasted chestnuts are collectively packed for subsequent reprocessing or direct consumption.
For example, the recycling member 500 is used to receive the fried auxiliary materials such as sugar, salt, sand and stone filtered by the filtering member 300, and simultaneously transfer the fried auxiliary materials back to the frying tool 200 for recycling.
Referring to fig. 2, which is a schematic structural diagram of a machine body 100 according to an embodiment of the present invention, the machine body 100 includes a support 110 and a frame 120. The bracket 110 is connected to the frame 120. In this embodiment, the bracket 110 and the frame 120 are made of metal materials.
For stability, the bracket 110 is integrally formed with the frame 120, for example. For example, the bracket 110 and the frame 120 are formed by one-step press molding. For example, the bracket 110 is welded to the frame 120.
For improved portability, for example, the stand 110 is detachably connected to the frame 120. For example, the bracket 110 is engaged with the frame 120. For example, the bracket 110 is inserted into the frame 120. For example, the bracket 110 is screwed with the frame 120.
As shown in fig. 2, the bracket 110 includes a plate body 111 and a plurality of support columns 112. For example, a plurality of support posts 112 are disposed on the same side of the plate body 111. For example, the plate body 111 is detachably connected to a plurality of support posts 112. Preferably, the plate body 111 is screwed with a plurality of support columns 112. For another example, the plate body 111 and the plurality of support pillars 112 are formed by one-time stamping and injection molding.
In this embodiment, the plate body 111 has a rectangular cross section. The bracket 110 includes four support posts 112. For example, four support columns 112 are respectively disposed at four corner regions of the plate body 111. For example, the supporting column 112 has a certain length, for example, the length of the supporting column 112 is 80-100 cm. Preferably, the support posts 112 are 90cm in length.
For example, the other side of the plate body 111 facing away from the support posts 112 is provided with a mounting region 1111, and the frame body 120 is disposed on the mounting region 1111. For example, the mounting section 1111 is located in a middle region of the board body 111. For example, the mounting region 1111 occupies 90% of the area of the side surface of the board body 111.
For stir-frying the chestnut to be stir-fried, for example, the body 100 has a stir-frying chamber 121. In this embodiment, the frame 120 forms the stir-frying chamber 121. The frying chamber 121 is used for installing and placing the frying tool 200 and providing a frying environment for the frying tool 200 so as to fry and process the Chinese chestnuts to be fried.
In this embodiment, the stir-frying chamber 121 has a hollow rectangular parallelepiped structure with an opening at one side. For example, the frying chamber 121 has a rectangular cross section to increase the length space of the frying chamber 121, that is, it has a longer frying space in two dimensions.
For example, the stir-fry chamber 121 is a hollow ellipsoidal structure with an opening. For example, the stir-fry chamber 121 has an elliptical cross-section to increase the width space of the stir-fry chamber 121, that is, it has a wider stir-fry space in two dimensions.
To achieve a good length space, the length-width-height ratio of the rectangular-section stir-frying chamber 121 is 4:2: 2. Preferably, the rectangular cross-section stir-fry chamber 121 has a ratio of length to width to height of 4.5:1.5: 2.
In order to reduce the effect of high temperature on the user, as shown in fig. 3, for example, the side wall 122 of the frame 120 includes a wear-resistant layer 1221, an explosion-proof layer 1222, and a thermal insulation layer 1223 connected in sequence from outside to inside.
For improving the wear resistance, for example, the wear-resistant layer 1221 includes the following components in parts by mass: mn: 30-65 parts of Cr: 10-25 parts of Mo: 4-13 parts, Re: 5-17 parts of Cu: 15-37 parts of Si: 23-45 parts of Ni: 3-9 parts of C: 2-5 parts of Al: 0.6 to 3 portions.
Thus, the wear-resistant layer 1221 can effectively prolong the service life of the frame body 120. Because in the process of frying the Chinese chestnuts, the frying tool can damage the box door to different degrees, for example, the cutter can scrape the outer surface of the box door, therefore, the wear-resistant layer 1221 can prevent the appearance from aging too fast to a certain extent, the service life of the box door is prolonged, resources are saved, and the production cost is reduced.
Preferably, the wear-resistant layer 1221 comprises the following components in parts by mass: mn: 65 parts of Cr: 10 parts of Mo: 4 parts and Re: 5 parts, Cu: 15 parts of Si: 23 parts of Ni: 3 parts and C: 2 parts of Al: 0.6 to 3 portions.
Preferably, the wear-resistant layer 1221 comprises the following components in parts by mass: mn: 30 parts of Cr: 25 parts of Mo: 13 parts, Re: 17 parts, Cu: 37 parts of Si: 45 parts of Ni: 9 parts and C: 5 parts of Al: and 3 parts.
Preferably, the wear-resistant layer 1221 includes the following components in parts by mass: mn: 45 parts of Cr: 15 parts of Mo: 7 parts and Re: 13 parts, Cu: 33 parts of, Si: 32 parts, Ni: 7 parts and C: 4 parts of Al: and 2 parts.
To improve the explosion-proof performance, the explosion-proof layer 1222 is made of explosion-proof glass, for example. For example, the explosion-proof glass is reinforced explosion-proof glass, that is, glass formed by sandwiching two or more pieces of float glass with a tough PVB film, pressing the glass by a hot press, exhausting intermediate air as much as possible, and then putting the glass into a high-pressure steam kettle to dissolve a small amount of residual air into an adhesive film by using high temperature and high pressure
For improving the heat insulation performance, for example, the heat insulation layer 1223 includes the following components in parts by mass: glass fiber powder: 43-65 parts of asbestos powder: 45-55 parts of rock wool powder: 12-27 parts of silicate: 19 to 25 portions.
So, can avoid effectively through insulating layer 1223 stir-fry the in-process, the heat conducts to the outside through the lateral wall 122 of framework 120, and the effectual heat source that produces of cutting off improves stir-fry efficiency to user's influence.
Preferably, the heat insulation layer 1223 comprises the following components in parts by mass: glass fiber powder: 43 parts of asbestos powder: 55 parts of rock wool powder: 27 parts of silicate: and 25 parts.
Preferably, the heat insulation layer 1223 comprises the following components in parts by mass: glass fiber powder: 65 parts of asbestos powder: 45 parts of rock wool powder: 12 parts of silicate: 19 parts of (A).
Preferably, the heat insulation layer 1223 comprises the following components in parts by mass: glass fiber powder: 55 parts of asbestos powder: 49 parts and rock wool powder: 23 parts of silicate: 21 parts.
To facilitate the discharge of the cooked chestnut processed in the frying chamber 121 to the outside, for example, the body 100 has a discharge port 123 communicating with the frying chamber 121, and it is understood that the discharge port 123 is used to discharge the cooked chestnut. Referring to fig. 2, in the present embodiment, the frame 120 is provided with the discharge port 123.
For facilitating the discharge, for example, the discharge port 123 is opened in a side wall of the frame body 120. For example, the discharge port 123 is adjacent to the plate body 111. For example, the discharge port 123 has a rectangular cross section. As another example, the discharge port 123 has a circular cross-section. For example, the cross-sectional area of the discharge port 123 is 70% of the sidewall of the frame 120. Therefore, the flow rate is increased through the larger cross-sectional area of the discharge port 123, and the roasted Chinese chestnuts can be conveniently discharged.
Referring to fig. 4, which is a schematic structural diagram of the body 100 and the door 130 thereof according to an embodiment of the present invention, for example, the body 100 is provided with the door 130. In this embodiment, the door 130 is disposed on the frame 120. For example, the door 130 is provided to cover the discharge port 123. For example, the door body 130 has a rectangular cross section. As another example, the door body 130 has a circular cross-section.
For opening the door 130, for example, the door 130 is pivotally connected to the frame 120. Referring to fig. 2 and 4, for example, the frame 120 is provided with a rotating shaft 124. The door 130 is disposed on the rotating shaft 124, so that the door 130 can rotate relative to the frame 120. Thus, the door 130 is very conveniently opened by the rotating shaft 124 so as to feed out the roasted chestnuts.
Referring to fig. 5, a schematic structural diagram of a frying tool 200 according to an embodiment of the present invention is shown, for example, the frying tool 200 is disposed in the frying chamber 121 for frying the chestnut to be fried. In this embodiment, the frying device 200 includes a base 210, a drum 220 and a frying member 230. For example, the housing 210 is connected to the drum 220. For example, the drum 220 has a cooking cavity 221, and the cooking member 230 is rotatably disposed in the cooking cavity 221.
For example, the base 210 has a rectangular parallelepiped structure. For example, the drum 220 is a hollow cylindrical structure. For example, the two sides of the rotating drum 220 are respectively provided with a rotating position 222, and the stir-frying member 230 is arranged between the rotating positions 222 on the two sides. For example, the frying pan 221 has a semicircular cross section. For example, the seat 210 is disposed in the stir-frying chamber 121, and in the embodiment, the seat 210 is disposed on the mounting region 1111.
To achieve the heating of the roasted chestnuts, for example, the seat body 210 has a heating area. For example, a heating element is disposed within the housing 210. For example, the heating element is located below the heating zone. For example, the heating member is electromagnetic heating. As another example, the heating element is a heating tube. For example, the bottom of the rotating cylinder 220 is correspondingly opened with a through opening. For example, the ports match the heating zones such that the chestnuts to be fried in the drum 220 are located above the heating zones.
So, the heating member during operation can heat the chinese chestnut of treating stir-fry that is located the zone of heating top to the system chinese chestnut is fried in the realization heating. In addition, since the heating technology is the prior art, the detailed description is omitted here.
Referring to fig. 6, which is a schematic structural diagram of a frying member 230 according to an embodiment of the present invention, for turning chestnuts during a frying process, for example, the frying member 230 includes a roller 231 and a plurality of shovels 232. For example, a plurality of spades 232 are uniformly disposed on the roller 231. For example, the plurality of shovels 232 are arranged at intervals. For example, the length of the spatula 232 matches the inner diameter of the stir channel 221 of the drum 220. Preferably, an end of the spatula 232 remote from the roller 231 abuts against an inner wall of the frying groove 221 to fry the chestnuts.
Referring to fig. 7, which is a schematic diagram illustrating a filter 300 according to an embodiment of the present invention, the filter includes a transmission frame 310 and a filter screen 320. In conjunction with fig. 1, for example, the transfer frame 310 is connected to the body 100. For example, the bottom of the conveying frame 310 is opened with a plurality of filtering ports 311. For example, the filter screen 320 is disposed at the bottom of the transfer frame 310. For example, the transfer frame 310 has a transfer passage 330, and the transfer passage 330 communicates with the discharge port 123.
If the conveying frame is of a metal grid structure and is obliquely arranged between the discharging port and the collecting box to form the conveying channel, the fried Chinese chestnuts roll to the collecting box from the discharging port under the action of gravity when passing through the conveying channel, and the fried auxiliary materials of the discharging port fall to the collecting part from grids in the metal grid structure along with the mistaken discharge of the fried Chinese chestnuts. For example, the maximum width of the meshes in the metal mesh structure is smaller than the minimum width of the roasted chestnut, and the maximum width of the meshes in the metal mesh structure is 40% or less of the minimum width of the roasted chestnut in order to facilitate the rolling of the roasted chestnut. For example, the metal mesh structure has a U-shaped or C-shaped cross section overall, with a central depression to form the transmission channel.
To improve the filtering effect, for example, a plurality of filtering ports 311 are distributed in a matrix at the bottom of the conveying frame 310. For example, the filter screen 320 covers the plurality of filter openings 311. For example, the outer diameter of the filtering port 311 is smaller than the minimum outer diameter of the chestnuts. For example, the outer diameter of the filtering port 311 is equal to 50% of the minimum outer diameter of the chestnuts. For another example, the filter screen 320 is made of metal wire.
Thus, after the fried Chinese chestnut and the frying auxiliary materials enter the transmission channel 330 together, the frying auxiliary materials pass through the filter screen 320 and pass through the filter opening 311, fall into the lower part of the conveying frame 310 under the action of gravity, and the fried Chinese chestnut continues to reach the collecting box 400 along the transmission channel 330 under the action of gravity, so that the fried Chinese chestnut and the frying auxiliary materials are separated, and the effect of effectively filtering the frying auxiliary materials is achieved.
Referring to fig. 8, which is a schematic structural view of a collection box 400 according to an embodiment of the present invention, in conjunction with fig. 1 and 7, for example, the collection box 400 is connected to an end of the conveying frame 310 away from the discharge port 123, and is used for collecting the fried chestnuts from the conveying frame 310.
In this embodiment, the collection box 400 includes a box body 410 and two support legs 420. For example, two support legs 420 are respectively provided at both sides of the case 410 to support the case 410. For example, the support legs 420 are detachably connected to the case 410; as another example, the support legs 420 are integrally injection molded with the case 410. In this embodiment, the support leg 420 is screwed to the case 410. For example, the box 410 is hinged to the end of the conveying frame 310 far from the discharge port 123 by a pin.
For receiving the roasted chestnuts, the collection box 400 has a receiving chamber 430, for example. In conjunction with fig. 7, for example, the receiving chamber 430 communicates with the transmission passage 330. In this embodiment, the case 410 has a hollow rectangular parallelepiped structure with one side open. For example, the accommodating chamber 430 has a certain depth to accommodate more chestnuts.
Referring to fig. 9, which is a schematic structural diagram of a recycling part 500 according to an embodiment of the present invention, for example, the recycling part 500 includes a collecting part 510 and a conveying part 520. For example, the aggregate part 510 is disposed below the conveying passage 330 of the conveying frame 310. in the embodiment, in conjunction with fig. 1, the aggregate part 510 is connected to the conveying frame 310 by two connecting rods 530, so that the aggregate part 510 is located below the conveying passage 330. For example, the connection rod 530 is screw-coupled with the transfer frame 310 and the sump 510, respectively. In this embodiment, the transfer part 520 has an arc structure.
To convey the cooking auxiliary materials from the conveying passage 330 to the conveying part 520, for example, the collecting part 510 includes a first motor 511 and a first conveyor belt 512. For example, the first motor 511 is connected to the first conveyor belt 512 to drive the first conveyor belt 512 to rotate.
Referring to fig. 1, for example, the projection of the conveying channel 330 in the vertical direction is located on the first conveyor belt 512, so that all the stir-fried auxiliary materials fall into the first conveyor belt 512.
For example, the conveying part 520 includes a second motor 521 and a second conveyor belt 522. For example, the second motor 521 is connected to the second conveyor belt 522 to drive the second conveyor belt 522 to rotate.
For example, the second conveyor belt 522 abuts the first conveyor belt 512, and an end of the second conveyor belt 522 remote from the first conveyor belt 512 is located within the stir-frying chamber 121. Referring to fig. 5, in this embodiment, an end of the second conveyor belt 522 away from the first conveyor belt 512 is located above the input port of the frying pan 221.
So, after the stir-fry auxiliary material falls into first conveyer belt 512, under the drive of first conveyer belt 512, will stir-fry auxiliary material and transmit to second conveyer belt 522 on to under the drive of second conveyer belt 522, will stir-fry auxiliary material and transmit back to stir-fry in the cavity 121, also transmit back to stir-fry in the groove 221.
Referring to fig. 10, which is a schematic structural diagram of a receiving member 600 according to an embodiment of the present invention, in conjunction with fig. 1, for example, the weighing type chestnut frying machine further includes a receiving member 600. In this embodiment, the receiving member 600 includes a receiving portion 610. For example, the bolster 610 is connected to the collection tank 400. In this embodiment, the receiving part 610 is hinged to the collecting chamber 400 by a pin to improve the flexibility of the receiving part 600.
In conjunction with fig. 8, for example, the collection box 400 is provided with a plurality of recovery ports 440 at the bottom thereof. For example, the projections of the plurality of recovery ports 440 in the vertical direction are located on the receiving portion 610. For example, a plurality of recovery ports 440 are distributed in a matrix at the bottom of the collection tank 400. For example, the plurality of recovery ports 440 are uniformly distributed at the bottom of the collection tank 400.
Since a part of the frying auxiliary materials is also attached to the roasted chestnuts entering the collecting box 400, in order to recycle the part of the frying auxiliary materials, that is, the frying auxiliary materials in the collecting box 400 are transferred to the frying chamber 121. For example, the receiving portion 610 is provided with a third motor and a third belt 612. The driving shaft of the third motor is connected to the third belt 612 to drive the third belt 612 to rotate. For example, a driving shaft 611 of a third motor is connected to the third belt 612 to drive the third belt 612 to rotate.
For example, a projection of the plurality of recovery ports 440 in the vertical direction is located on the third conveyor belt 612. For example, the end of the third conveyor belt 612 remote from the collection bin 400 is located above the first conveyor belt 512. For example, the third conveyor belt 612 has an arc-shaped structure.
For example, the width of the third conveyor belt 612 is equal to 1 to 2.3 times the width of the collection box 400. For example, the width of the third conveyor belt 612 is equal to the width of the collection bin 400. For example, the width of the third conveyor belt 612 is equal to 1.5 times the width of the collection bin 400.
Therefore, the stir-fried auxiliary materials entering the collection box 400 fall onto the third conveyor belt 612 through the recovery ports 440, the stir-fried auxiliary materials are conveyed onto the first conveyor belt 512 under the driving of the third motor, and the stir-fried auxiliary materials are conveyed to the stir-frying chamber under the driving of the first conveyor belt 512 and the second conveyor belt 522.
Referring again to fig. 8, in order to lower the temperature of the roasted chestnuts in the collection container 400, for example, the collection container 400 is provided with a temperature detector 450. It is understood that the temperature detector 450 serves to sense the temperature of the roasted chestnuts within the collection container 400. For example, the weighing type chestnut frying machine further includes a fan (not shown) connected to the body 100.
For example, the fan is connected to a temperature detector 450, and the temperature detector 450 controls the start and stop of the fan. For example, the air outlet of the blower faces the collection box 400 to supply air to the collection box 400, thereby reducing the temperature of the fried chestnuts. For example, the collection box 400 is provided with an air inlet, and an air outlet of the blower is communicated with the air inlet through a conduit.
For example, the conduit has a circular cross-section. For example, the conduit has an arcuate configuration. For example, the collection tank 400 is provided with a mounting seat to which the temperature detector 450 is detachably connected. For example, the probe of the temperature detector 450 is located in the middle of the collection tank 400. For example, temperature detector 450 comprises an infrared temperature detector.
Thus, when the temperature detector 450 senses that the temperature of the fried Chinese chestnut in the collection box 400 is above the preset value, that is, the temperature of the fried Chinese chestnut is higher, the fan is started to supply air to the fried Chinese chestnut, and the temperature of the fried Chinese chestnut in the collection box 400 is reduced in an air cooling mode, so that a user can conveniently take the Chinese chestnut.
Referring to fig. 11, for example, the weighing chestnut frying machine further includes a vibrating device 700. For example, the vibration device 700 is connected to the transfer frame 310, and when the vibration device 700 is turned on, the transfer frame 310 is driven to vibrate to assist the flow of the roasted chestnuts and the roasted auxiliary materials in the transfer passage 330, thereby screening the roasted auxiliary materials. For example, a weight sensor connected to the vibration device is further provided, and the vibration device is automatically activated to drive the conveying frame 310 to vibrate when the roasted chestnut is sensed to appear.
In order to quickly screen the frying auxiliary materials from the conveying frame 310, for example, the bracket 110 is provided with a chute 115. Referring to fig. 2, in the present embodiment, the sliding groove 115 is opened on the plate 111. For example, the chute 115 has a semicircular cross section. For example, the transfer frame 310 is disposed on the chute 115. In conjunction with fig. 7 and 12, for example, the conveying frame 310 is provided with a slide rail 350. For example, the slide rail 350 is embedded in the slide groove 115. For example, the slide rail 350 has a semicircular cross section.
In conjunction with fig. 1 and 11, for example, a vibration device 700 includes a housing 710 and a piston 720. For example, the piston 720 is disposed on the housing 710. For example, the housing 710 is disposed on the bracket 110. For example, the piston 720 is connected to the transfer frame 310, and the traveling direction of the piston 720 is parallel to the length direction of the chute 115.
So, under the drive of piston 720, conveying frame 310 forms the effect of vibration along the length direction reciprocating motion of spout 115 to select the stir-fry system auxiliary material for an accelerated time, improved efficiency.
To prevent the conveying frame 310 from leaving the sliding groove 115, referring to fig. 12, for example, the bracket 110 further includes a stopper 116. For example, the stopper 116 is located above the sliding groove 115. For example, the stop 116 is hinged to the bracket 110. For example, the sliding rail 350 is correspondingly provided with a notch 351. For example, the notch 351 matches the stop 116. For example, the stopper 116 is hinged to the bracket 110 by a pin 117.
So, stopper 116 card is established in breach 351, can increase the friction of slide rail 350 and spout 115 to prevent that slide rail 350 from leaving spout 115, and then prevent that conveying frame 310 from leaving spout 115, improve and select the efficiency of stir-fry system auxiliary material.
To improve the vibration effect, for example, the side wall of the sliding groove 115 is provided with an elastic member, and the elastic member abuts against the sliding rail 350. For example, the elastic member is a spring. So, can effectual increase vibration effect through the elastic component, improve and select the efficiency of stir-fry system auxiliary material.
Referring to fig. 13, for example, the weighing type chestnut frying machine further includes a weighing device 800. For example, a weighing device 800 is provided on the body 100 for weighing the roasted chestnuts. For example, the body 100 is provided with a mounting plate 180, and the weighing device 800 is detachably provided on the mounting plate 180. For example, the weighing apparatus 800 is bolted to the mounting plate 180 to improve portability and to facilitate replacement and maintenance of the weighing apparatus 800.
Referring to fig. 14, for example, a weighing apparatus 800 includes a base 810. For example, the base 810 is coupled to the mounting plate 180. For example, a load cell 820 is disposed within the base 810. For example, the base 810 has a weighing area 830 thereon for holding roasted chestnuts.
To improve portability, for example, the weighing apparatus 800 further includes a tray 840. For example, a tray 840 is placed on the weighing region 830. For example, the plate 840 has a groove. For example, the plate 840 has a hemispherical structure.
So, when weighing, utilize the disk body 840 to load into fried chinese chestnut in order to weigh, can take away disk body 840 after weighing, convenient and fast.
Referring again to fig. 13, for example, the weighing chestnut roaster further comprises a display 900. For example, the display 900 is disposed on the body 100. For example, the display 900 is connected to the weighing apparatus 800 to display weighing data of the weighing apparatus 800. For example, a speaker is further included, and the speaker is connected to the display 900 to broadcast the value displayed by the display 900.
The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.