Air supply assembly and integrated cooker
By designing a planar four-bar linkage for the air supply component, the airflow direction is adjusted to address the issue of temperature rise during kitchen cooking. This achieves flexible airflow adjustment and a highly stable air supply effect, thereby improving user comfort.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- WUHU MIDEA SMART KITCHEN APPLIANCE MFG CO LTD
- Filing Date
- 2022-05-17
- Publication Date
- 2026-07-10
AI Technical Summary
When cooking in the kitchen, the ambient temperature around the stove rises, causing discomfort to the cook. Existing technology makes it difficult to effectively adjust the airflow to improve user comfort.
Design an air supply component including an air supply frame, a rotating component, a transmission component, and an air guide plate, which are connected by a planar four-bar linkage to achieve airflow direction adjustment. The structure is simple and highly stable. The air supply component can be combined with an integrated stove to adjust the airflow direction to improve user comfort.
It enables flexible adjustment of airflow direction, improves user comfort while cooking in the kitchen, reduces the temperature near the stove, and enhances the stability and effectiveness of the air supply components.
Smart Images

Figure CN117109040B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of electrical equipment technology, and in particular to an air supply component and an integrated stove having the air supply component. Background Technology
[0002] With social progress and development, people have higher requirements for the comfort of their living environment. When cooking in the kitchen, the ambient temperature around the stove is high, especially in the hot summer. This can cause cooks to sweat profusely, leading to a very unpleasant experience. Summary of the Invention
[0003] This invention aims to at least partially solve one of the technical problems in related technologies. Therefore, one objective of this invention is to provide an air supply assembly that can adjust the swing angle of the air guide plate to achieve airflow direction adjustment, and which has a simple structure, high stability, and can improve user comfort.
[0004] Another object of the present invention is to provide an integrated stove including the aforementioned air supply component.
[0005] According to an embodiment of the present invention, an air supply assembly includes: an air supply frame, a rotating component, a transmission component, and an air guide plate. The rotating component is rotatably connected to the air supply frame; the transmission component is rotatably connected to the rotating component; and the air guide plate is rotatably connected to the air supply frame and rotatably connected to the transmission component. The rotating component, the transmission component, and the air guide plate are connected to form a planar four-bar linkage.
[0006] The air supply assembly according to the embodiments of the present invention can adjust the swing angle of the air guide plate to achieve air direction adjustment, and has a simple structure and high stability.
[0007] In addition, the air supply assembly according to the above embodiments of the present invention may also have the following additional technical features:
[0008] In some embodiments, the air guide plate includes multiple air guide plates, all of which are connected to the same transmission member, and the multiple air guide plates are driven by the transmission member to rotate synchronously.
[0009] In some embodiments, the transmission component includes a main body and a plurality of branches, each of the branches being connected to the main body. The main body is rotatably connected to the rotating component. Each of the branches corresponds to a plurality of air guide plates, and each branch is rotatably connected to a corresponding air guide plate.
[0010] In some embodiments, the transmission component is integrally formed.
[0011] In some embodiments, the air supply frame is provided with a first limiting structure, and the rotating member is provided with a second limiting structure. The first limiting structure and the second limiting structure cooperate to limit the rotation angle of the rotating member.
[0012] In some embodiments, the first limiting structure is a limiting groove, the second limiting structure is a limiting slider, and the limiting slider is slidably embedded in the limiting groove.
[0013] In some embodiments, the rotating component includes an inner turntable and an outer turntable, wherein the inner turntable is rotatably disposed inside the air supply frame; the outer turntable is disposed outside the air supply frame and is fixedly connected to the inner turntable, wherein the transmission component is eccentrically connected to the inner turntable, and the outer turntable is used to connect to the driving component.
[0014] In some embodiments, one of the inner turntable and the outer turntable is provided with a positioning pin and the other is provided with a positioning hole, the positioning pin is embedded in the positioning hole, and the inner turntable and the outer turntable are connected by fasteners.
[0015] In some embodiments, the air supply frame is provided with mounting holes, the inner turntable is provided with a stepped portion and a rotating shaft portion, the stepped portion is provided on the inner turntable, the rotating shaft portion is provided on the stepped portion and is rotatably embedded in the mounting holes, and the periphery of the stepped portion is opposite to the inner side surface of the air supply frame.
[0016] In some embodiments, the air supply frame is configured as a rectangular frame extending along a first direction, the air guide plate extends along the first direction and is rotatably connected to both ends of the air supply frame, the rotating member is rotatably disposed at the end of the air supply frame, and the rotation center axis of the rotating member is parallel to the first direction.
[0017] An integrated stove according to an embodiment of the present invention includes: a stove body, the aforementioned air supply assembly, and a driving component, wherein the air supply assembly is disposed on the stove body; and the driving component is disposed on the stove body and is pulsatorically connected to the rotating component.
[0018] The integrated stove according to an embodiment of the present invention has a ventilation function, which can realize airflow direction adjustment, thereby improving user comfort.
[0019] In some embodiments, the air supply assembly is configured to supply air along a third direction and is detachably connected to the cooktop along the third direction, and the rotating member is detachably connected to the drive member along the third direction, wherein the third direction is perpendicular to the rotation center axis of the rotating member.
[0020] In some embodiments, the air supply frame is configured as a rectangular frame extending along a first direction, the drive member is disposed on the outer side of the end of the air supply frame, and the drive member and the air supply frame are opposite each other along the first direction.
[0021] In some embodiments, the cooktop body integrates an air conditioning mechanism, which is connected to the air supply assembly. Attached Figure Description
[0022] Figure 1 This is a schematic diagram of the integrated stove in some embodiments of the present invention.
[0023] Figure 2 yes Figure 1 A sectional view (showing a planar four-bar linkage structure constructed from rotating parts, transmission parts, and air guide plates).
[0024] Figure 3 yes Figure 1 A cross-sectional view (showing the state when the limiting slide and the limiting slider are engaged).
[0025] Figure 4 yes Figure 1 A cross-sectional view (showing the state when the limiting groove and the limiting slider are separated).
[0026] Figure 5 yes Figure 1 Side view.
[0027] Figure 6 This is a schematic diagram of the integrated stove structure in some embodiments of the present invention (where the air guide plate is not shown).
[0028] Figure 7 This is a schematic diagram of the integrated stove in some embodiments of the present invention (showing the state when the air supply component is separated from the stove body).
[0029] Figure 8 This is a schematic diagram of the structure of the rotating member and the first connecting part in some embodiments of the present invention.
[0030] Figure 9 This is a schematic diagram of the structure of the rotating component and the first connecting part in some embodiments of the present invention (showing the state when the inner turntable and the outer turntable are separated).
[0031] Figure 10 This is a schematic diagram of the structure of the rotating component in some embodiments of the present invention.
[0032] Figure 11 These are schematic diagrams of the integrated stove in some embodiments of the present invention (showing the state of the integrated stove when applied in the kitchen).
[0033] Figure 12These are schematic diagrams of the integrated stove in some embodiments of the present invention (showing the state of the integrated stove when applied in the kitchen).
[0034] Figure label:
[0035] 100. Integrated cooktop; 1. Air supply assembly; 11. Air supply frame; 101. Limiting slide groove; 11a. First end plate; 11b. Second end plate; 11c. Extension plate; 105. Hook; 12. Limiting slider; 131. Outer turntable; 132. Inner turntable; 1322. Stepped part; 1321. Rotating shaft part; 103. Positioning hole; 133. Positioning pin; 13. Rotating component; 14. Transmission component; 141. Main body part; 142. Support part; 15. Air guide plate; 16. Air guide blade; 17. Rotating component; 171. Rotating part; 172. Inclined plate part; 174. Connecting turntable; 18. Intermediate component; 19. Connecting component; 2. Stove body; 3. Driving component; 4. Locking mechanism; 102. Slot; 41. Reset component; 42. Pressing part; 520. Mating groove; 51. First connecting part; 52. Second connecting part. Detailed Implementation
[0036] Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the accompanying drawings are exemplary and intended to explain the present invention, and should not be construed as limiting the present invention.
[0037] Combination Figures 1 to 12 According to an embodiment of the present invention, the air supply assembly 1 includes an air supply frame 11 and an air guide plate 15. The air guide plate 15 is mounted on the air supply frame 11 and is rotatable on the air supply frame 11, thereby adjusting the air supply direction. Further, a rotating member 13 and a transmission member 14 are included between the air supply frame 11 and the air guide plate 15. The rotating member 13 is rotatably connected to the air supply frame 11, and the transmission member 14 is connected between the rotating member 13 and the air guide plate 15, serving to transmit power. The transmission member 14 is rotatably connected to the rotating member 13, and the air guide plate 15 is rotatably connected to the transmission member 14. In other words, by sequentially and rotatably connecting the air supply frame 11, the rotating member 13, the transmission member 14, and the air guide plate 15, power can be transmitted from the rotating member 13 to the air guide plate 15, allowing the air guide plate 15 to rotate on the air supply frame 11, thereby achieving adjustment of the air supply direction of the air supply assembly 1. Furthermore, the rotating component 13, the transmission component 14, and the air guide plate 15 are connected to form a planar four-bar linkage, which can achieve surface contact, and the air guide plate 15 directly serves as a connecting rod of the planar four-bar linkage (see...). Figure 2 The planar four-bar linkage (A) in the middle is beneficial to improving rotational stability and durability. Its simple structure is easy to construct and helps to improve manufacturing precision, thereby enhancing the performance of the air supply assembly 1.
[0038] According to the embodiment of the present invention, the air supply assembly 1 connects the rotating member 13, the transmission member 14 and the air guide plate 15 into a planar four-bar linkage, which can adjust the swing angle of the air guide plate 15 to achieve air direction adjustment. It has a simple structure, high stability and can improve user comfort.
[0039] In practical applications, the drive component 3 can drive the rotating component 13 to rotate relative to the air supply frame 11, and the transmission component 14 can transmit the rotation of the rotating component 13 to the air guide plate 15, so that the air guide plate 15 rotates relative to the air supply frame 11. The direction of air supply can be adjusted by rotating the air guide plate 15 to different positions. For example, when the air guide plate 15 rotates to an upward tilt and remains stationary, it can guide the air upward; when the air guide plate 15 rotates continuously so that it can swing up and down, it can achieve the effect of upward and downward air sweeping. Users can adjust it according to actual needs to improve user comfort.
[0040] Alternatively, the air supply assembly 1 may not include the rotating part 13 and the transmission part 14. The user can manually adjust the angle of the air guide plate 15, or the user can adjust the angle of the air guide plate 15 manually without using the rotating part 13 and the transmission part 14.
[0041] Combination Figure 1 and Figure 7 In some embodiments, multiple air guide plates 15 are included, which can improve the accuracy of airflow direction adjustment. Each of the multiple air guide plates 15 is connected to the same transmission component 14, and the multiple air guide plates 15 are driven by the transmission component 14 to rotate synchronously. That is, the multiple air guide plates 15 can be controlled as a whole, which simplifies the structure of the air supply assembly 1, improves operational stability, and achieves energy saving. Furthermore, the multiple air guide plates 15 can operate synchronously, and multiple air guide plates 15 can be translated, improving the accuracy of airflow direction adjustment.
[0042] Combination Figure 1 Optionally, the multiple air guide plates 15 can be configured to be shaped to close the air supply frame 11. In this way, when air guidance is not required, the air supply frame 11 can be closed by multiple air guide plates 15. When air guidance is required, compared with the structure of closing the air supply frame 11 by using one air guide plate 15, the width of the air guide plate 15 is smaller when multiple air guide plates 15 are used to close the air supply frame 11, which can facilitate air guidance over a larger range, making it easier to control and facilitate air guidance.
[0043] Optionally, the multiple air guide vanes 15 can also be connected to multiple transmission components 14 respectively, so as to realize the individual adjustment and control of the multiple air guide vanes 15.
[0044] Furthermore, combined Figure 2The transmission component 14 includes a main body 141 and multiple branches 142, each branch 142 being connected to the main body 141. The main body 141 is rotatably connected to the rotating component 13. Each branch 142 corresponds to a multiple air guide vanes 15, and each branch 142 is rotatably connected to its corresponding air guide vane 15. Thus, when the main body 141 rotates, the multiple branches 142 can rotate along with it. For example, one end of a branch 142 can be connected to the main body 141, and the other end of the branch 142 extends away from the main body 141 to connect to a guide vane. The multiple branches 142 connected to the main body 141 can drive the multiple air guide vanes 15 to rotate, thereby improving transmission efficiency.
[0045] In some embodiments, the transmission component 14 is integrally formed, which can improve structural stability and facilitate manufacturing and assembly.
[0046] According to some embodiments of the air supply assembly 1 of the present invention, the transmission member 14 includes a main body 141 and two branches 142. The two branches 142 are connected to the main body 141 to form a "U"-shaped structure, and the two branches 142 are respectively connected to two air guide plates 15. Of course, depending on the actual situation, the air supply assembly 1 may have multiple air guide plates 15. Therefore, the main body 141 may also be connected to three branches 142, or multiple transmission members 14 may be provided, etc. The present invention is not limited thereto.
[0047] Combination Figure 2 In some embodiments, the air supply frame 11 is provided with a first limiting structure, and the rotating member 13 is provided with a second limiting structure. The first limiting structure and the second limiting structure cooperate to limit the rotation angle of the rotating member 13. Specifically, the first limiting structure can limit the rotation range of the rotating member 13, thereby limiting the rotation range of the air guide plate 15, improving the accuracy and operational stability of air supply, and thus improving user comfort.
[0048] In some embodiments, the first limiting structure is a limiting groove 101, and the second limiting structure is a limiting slider 12, with the limiting slider 12 slidably embedded in the limiting groove 101. That is, the first limiting structure can limit the rotation range of the rotating member 13. Specifically, the limiting slider 12 is located on the rotating member 13 and embedded in the limiting groove 101. When the rotating member 13 rotates, the limiting groove 101 can slide within it. When the limiting slider 12 slides to the end point of the limiting groove 101, it is restricted and cannot continue to slide, thus preventing the rotating member 13 from continuing to slide, thereby limiting the maximum swing angle of the air guide plate 15. In practical applications, the dimensions of the first and second limiting structures can be limited according to actual needs so that the air guide plate 15 can rotate within a predetermined range.
[0049] In practical applications, the shape of the limiting groove 101 can be constructed according to the movement trajectory of the rotating part 13, so that the slider can slide smoothly in the groove.
[0050] Combination Figure 2 , Figure 8 and Figure 9 In some embodiments, the rotating component 13 includes an inner turntable 132 and an outer turntable 131. The inner turntable 132 is rotatably disposed inside the air supply frame 11; the outer turntable 131 is disposed outside the air supply frame 11 and is fixedly connected to the inner turntable 132. Specifically, the inner turntable 132 is connected to the outer turntable 131, and the inner turntable 132 and the outer turntable 131 can rotate synchronously. The air supply frame 11 is sandwiched between the inner turntable 132 and the outer turntable 131, which can play a positioning role, thereby improving the stability of the cooperation between the rotating component 13 and the air supply frame 11, and facilitating assembly and maintenance. The outer turntable 131 is used to connect to the driving component 3, which can provide driving force for the rotating component 13. In application, the outer turntable 131 can be driven from outside the air supply frame 11, and the outer turntable 131 transmits power to the inner turntable 132, which is beneficial for improving stability and facilitating flexible spatial arrangement.
[0051] Furthermore, the eccentric connection between the transmission component 14 and the inner turntable 132 can improve the transmission ratio, which is beneficial for increasing the rotation range of the transmission component 14 and reducing its volume. It also has a simple structure and is easy to construct.
[0052] Combination Figure 8 and Figure 9 In some embodiments, one of the inner turntable 132 and the outer turntable 131 is provided with a positioning pin 133 and the other is provided with a positioning hole 103. The positioning pin 133 is embedded in the positioning hole 103, and the inner turntable 132 and the outer turntable 131 are connected by fasteners, which can realize the fixed connection between the inner turntable 132 and the outer turntable 131, which is easy to manufacture and has high stability. Among them, the inner turntable 132 and the outer turntable 131 can be concentrically connected, that is, the positioning pin 133 or the positioning hole 103 is located on the rotation center axis of the inner turntable 132 or the outer turntable 131.
[0053] In some embodiments, the air supply frame 11 is provided with mounting holes, and the inner turntable 132 is provided with a stepped portion 1322 and a rotating shaft portion 1321. The stepped portion 1322 is provided on the inner turntable 132, and the rotating shaft portion 1321 is provided on the stepped portion 1322 and rotatably embedded in the mounting holes. Specifically, the mounting holes can be used to install the rotating shaft portion 1321, which is rotatably embedded in the mounting holes. The rotating shaft portion 1321 is connected to the stepped portion 1322, allowing the stepped portion 1322 to be rotatably mounted on the air supply frame 11. Further, the stepped portion 1322 can be used to connect the transmission component 14. The periphery of the stepped portion 1322 is opposite to the inner surface of the air supply frame 11, and there is a gap between the stepped portion 1322 and the air supply frame 11. The stepped portion 1322 can rotate relative to the air supply frame 11 without interfering with it, which helps to improve operational stability.
[0054] In some embodiments, the air supply frame 11 is constructed as a rectangular frame extending along a first direction, which facilitates spatial arrangement and extends the air outlet range in the first direction, thus improving user comfort. The air outlet guide plate 15 extends along the first direction and is rotatably connected to both ends of the air supply frame 11. In this way, the air supplied from the air supply frame 11 can be guided by the guide plate 15 before being delivered, improving air supply accuracy. Specifically, the rotating member 13 is rotatably disposed at the end of the air supply frame 11, and the guide plate 15 is rotatably connected to the rotating member 13. The guide plate 15 can be positioned at both ends of the air supply frame 11 by connecting to the rotating member 13 and is rotatable relative to both ends of the air supply frame 11. More specifically, the rotation center axis of the rotating member 13 is parallel to the first direction. Therefore, when the rotating member 13 rotates, the transmission member 14 can follow the rotating member 13 and translate in a second direction, thereby driving the guide plate 15 to translate in the second direction.
[0055] See Figure 1 and Figure 7The first direction can be left-right, the second direction can be up-down, and the third direction can be front-back. According to some embodiments of the present invention, the air supply assembly 1 includes an air supply frame 11, a rotating member 13, a transmission member 14, and an air guide plate 15. Specifically, the air supply frame 11 extends in the left-right direction and has an opening for air supply at its front. The air guide plate 15 also extends in the left-right direction, and its left and right ends are connected to the end plates of the air supply frame 11. The rotating member 13 is rotatably connected to the left side of the air supply frame 11, and the transmission member 14 is rotatably connected to the rotating member 13. The transmission member 14 has a U-shaped structure with its opening facing forward and can connect two air guide plates 15. When the rotating member 13 rotates, the air guide plates 15 can swing in the up-down direction, allowing adjustment of the air supply direction in the up-down direction. Furthermore, the rotating component 13 is provided with a limiting slider 12, and a limiting groove 101 is constructed on the end plate of the air supply frame 11. The limiting slider 12 can be embedded in the limiting groove 101, which can limit the maximum angle of the guide plate swinging up or down. The limiting groove 101 can extend in an arc shape to accommodate the rotation of the rotating component 13.
[0056] Furthermore, in conjunction with the vent 2, the rotating component 13, the transmission component 14, and the air guide plate 15 are connected to the air supply frame 11 via a low-pair connection to form a planar four-bar linkage. The air supply frame 11 and the rotating component 13 form a frame, and the rotating component 13 and the transmission component 14 can rotate within a certain range to form a rocker structure, allowing the air guide plate 15 to swing within a certain range. The air guide plate 15 acts as a connecting rod. In this way, the air guide plate 15 can be directly connected to the air supply assembly 1 to form an integral structure, which simplifies the structure and improves the overall stability of the device.
[0057] In conjunction with 3, in some embodiments of the present invention, the air supply assembly 1 further includes a guide vane 16, a rotating member 17, and an intermediate member 18. The air supply frame 11 extends along a first direction and can supply air along a third direction. The guide plate 15 extends along the first direction. The guide vane 16 is disposed in the air supply frame 11 and extends along a second direction. The rotating member 17 and the rotating member 13 are respectively disposed on the end plates at both ends of the air supply frame 11 in the first direction. The rotating member 13, the transmission member 14, and the guide plate 15 are connected to form a planar four-bar linkage mechanism. The rotating member 17, the intermediate member 18, and the guide vane 16 are connected to form a spatial four-bar linkage mechanism.
[0058] Among them, combined Figure 6The upper and lower ends of the guide vane 16 are rotatably connected to the air supply frame 11. Air delivered from the air supply frame 11 can be guided by the guide vane 16 before being delivered, further improving air delivery accuracy. The rotating component 17 drives the guide vane 16 to rotate, allowing it to rotate at the air outlet of the air supply frame 11 and adjust the airflow direction. Multiple guide vanes 16 are included, improving the accuracy of airflow adjustment. The rotating component 17 is driven by one of the multiple guide vanes 16, and connecting components 19 connect the multiple guide vanes 16. Thus, the multiple guide vanes 16 are interconnected. When the driving component 14 drives one guide vane 16 to rotate, the multiple guide vanes 16 connected to that vane can rotate synchronously. Furthermore, the connecting components 19 are eccentrically connected to the multiple guide vanes 16 to ensure synchronous rotation. The multiple guide vanes 16 do not require individual control, simplifying the structure of the air supply assembly 1, improving operational stability, and achieving energy savings. Among them, the air guide plate 15 and the air guide blade 16 can be plate-shaped structures.
[0059] Combination Figures 2 to 7 On the left side of the air supply frame 11, the drive component 3 is sequentially connected to the rotating component 13, the transmission component 14, and the air guide plate 15, allowing control of the air guide plate 15 to swing in a second direction. On the right side of the air supply frame 11, the drive component 3 is sequentially connected to the rotating component 17, the intermediate component 18, and the air guide blade 16, allowing control of the air guide blade 16 to swing in a first direction. Thus, the combination of the air guide plate 15 and the air guide blade 16 allows for adjustment of the airflow direction in multiple directions, improving the accuracy of the air supply direction and enhancing the functionality of the air supply assembly 1. For example, when air is blown out from a third direction, it can be guided by the air guide plate 15 or the air guide blade 16 during the air supply process, achieving multi-angle airflow and improving user comfort.
[0060] Combination Figure 3 and Figure 6 In some embodiments, the rotating member 17 can rotate around a first rotational central axis, and the rotating member 17 is connected to the air supply frame 11 around the first rotational central axis; the guide vane 16 can rotate around a second rotational central axis, and the guide vane 16 is connected to the air supply frame 11 around the second rotational central axis, wherein there is an included angle between the first rotational central axis and the second rotational central axis, and the guide vane 16 and the rotating member 17 are opposite each other along the first rotational central axis. That is, through the transmission of the intermediate member 18, the rotation direction can be changed from rotation around the first rotational central axis to rotation around the second rotational central axis, so that the guide vane 16 can rotate around the second rotational central axis, so that the guide vane 16 can rotate in a predetermined direction to achieve airflow adjustment. In other words, the air supply assembly 1 in some embodiments of the present invention can be flexibly arranged according to different shapes and structures of the air supply assembly 1.
[0061] In some embodiments, the first and second rotational axes are perpendicular to each other, which helps to improve structural stability and facilitates arrangement.
[0062] In some embodiments, the intermediate component 18 can rotate about a third rotational axis. The intermediate component 18 is connected to the rotating component 17 about the third rotational axis, and the third rotational axis has an angle with both the first and second rotational axes. The intermediate component 18 can both transmit power between the rotating component 17 and the guide vane 16 and change the direction of transmission, so that the rotating component 17, the intermediate component 18, and the guide vane 16 can form spatial movement among each other.
[0063] Combination Figure 6 and Figure 10 Furthermore, the rotating member 17 includes a rotating portion 171 and an inclined plate portion 172. The rotating portion 171 is rotatably connected to the air supply frame 11; the inclined plate portion 172 is connected to the rotating portion 171 and extends in a direction perpendicular to the third rotation center axis, wherein the intermediate member 18 is rotatably connected to the inclined plate portion 172. That is, the rotating portion 171 can be connected to the air supply frame 11, the inclined plate portion 172 extends into the air supply frame 11 and is connected to the intermediate member 18, which can transmit power to the intermediate member 18. Furthermore, the inclined plate portion 172 extends in a direction perpendicular to the third rotation center axis, which can convert the movement of the rotating portion 171 in the direction of the first rotation center axis into the movement of the intermediate member 18 in the direction of the third rotation center axis, thereby realizing the change of transmission direction. Therefore, the inclined plate portion 172 has an angle with the first rotation center axis. In conjunction with the above, the intermediate member 18 also has an angle with the second rotation center axis. Thus, through the variable shaft angle transmission of the inclined plate portion 172 and the transmission portion, the power of the rotating member 17 can be transmitted to the guide vane 16, and the guide vane 16 can rotate along the second rotation center axis, so that the air direction can be adjusted according to a predetermined angle, improving the accuracy of the air supply direction and thus enhancing the user's comfort.
[0064] In some embodiments, the intermediate component 18 is movably connected to the rotating component 17 along the third rotation center axis, which can increase the rotation range of the guide vane 16 and improve the accuracy of the guide vane 16 in adjusting the wind direction.
[0065] Combination Figure 6 In some embodiments, the intermediate component 18 is connected to the guide vane 16 around the fourth rotation center axis. The intermediate component 18 can rotate around the fourth rotation center axis, and the fourth rotation center axis has an angle with both the third rotation center axis and the second rotation center axis. Thus, when the intermediate component 18 extends along the direction of the third rotation center axis and rotates around the fourth rotation center axis, the rotation direction of the guide vane 16 can be changed to the direction of rotation of the guide vane 16 along the direction of the second rotation center axis.
[0066] In some embodiments, the fourth rotation center axis is perpendicular to both the third and second rotation center axes, which can improve the stability of the structure, thereby enhancing the stability of the transmission, increasing the durability of the device, and facilitating manufacturing.
[0067] Optionally, the air guide plate 15 and the air guide blade 16 can be plate-shaped structures, wherein the upper end of the air guide plate 15 can be constructed with a wedge-shaped surface to guide the airflow.
[0068] Combination Figures 1 to 12 According to an embodiment of the present invention, the integrated stove 100 includes: a stove body 2, the aforementioned air supply assembly 1, and a drive component 3. The air supply assembly 1 is disposed on the stove body 2; the drive component 3 is disposed on the stove body 2 and is pulsatorically connected to the rotating component 13. Specifically, the stove body 2 can be used for cooking. Since the area around the stove body 2 heats up quickly after the stove body 2 is turned on, and the ambient temperature rises, the air supply assembly 1 on the integrated stove 100 can deliver cool air to the user to improve user comfort. Specifically, the air supply assembly 1, disposed on the stove body 2, can deliver air to the user, for example, deliver cold air to reduce the temperature near the stove body 2 and improve user comfort. More specifically, the integrated stove 100 also includes the drive component 3, which can drive the air guide plate 15 on the air supply assembly 1 to swing, thereby adjusting the air outlet angle and further improving user comfort. For example, when the user's head is sweating and they need the air to blow upwards, they can adjust the angle of the air guide plate 15 to direct the air upwards.
[0069] According to an embodiment of the present invention, the integrated stove 100 can improve the user's comfort when using the integrated stove 100 by providing an air supply component 1 and the air supply angle of the air supply component 1 being adjustable.
[0070] In some embodiments, the air supply assembly 1 is configured to supply air in a third direction and is detachably connected to the cooktop 2 in the third direction, and the rotating member 13 is detachably connected to the drive member 3 in the third direction, wherein the third direction is perpendicular to the rotation center axis of the rotating member 13. Specifically, the air supply assembly 1 can be configured to supply air toward the user or the kitchen space, and the air supply assembly 1 can be detached in this direction. This improves the user's comfort when using the air supply assembly 1. In addition, since there is a lot of oil smoke near the cooktop 2, which may pollute the air supply assembly 1, the user can periodically disassemble the air supply assembly 1 for cleaning to improve cleanliness.
[0071] The rotation center axis of the rotating component 13 is parallel to the left-right direction and perpendicular to the air supply direction, i.e., the front-back direction. The air supply assembly 1 can supply air in the front-back direction, can blow air towards the user, and is detachable in the front-back direction for easy user maintenance.
[0072] Furthermore, the integrated stove 100 also includes a locking mechanism 4, which is connected to the stove body 2 and is movable between a locked position and a released position. In the locked position, the locking mechanism 4 can lock the air supply component 1 to position the air supply component 1 on the stove body 2. In the released position, the locking mechanism 4 can release the air supply component 1 so that the air supply component 1 can be detached.
[0073] Combination Figure 5 Furthermore, the locking mechanism 4 is provided with a slot 102, and the air supply assembly 1 is provided with a hook 105, which can engage with the slot 102. Specifically, when the locking mechanism 4 is in the released position, the hook 105 is adapted to insert into and disengage from the slot 102 to separate the air supply assembly 1 from the locking mechanism 4. When the locking mechanism 4 is in the locked position, the slot 102 of the locking mechanism 4 is adapted to engage with the hook 105 inserted into the slot 102 to fix and lock the air supply assembly 1. Multiple hooks 105 and slots 102 can be provided in the direction of engagement between the locking structure and the air supply assembly 1 to improve the stability of the locking. For example, two slots 102 and hooks 105 can be symmetrically provided in the second direction. More specifically, the hook 105 can include a head and a rod, the rod being connected to the extension plate 11c, and the head being constructed in a wedge shape to facilitate entry into the slot 102.
[0074] In some embodiments, the integrated stove 100 further includes a reset member 41, which is connected to the stove body 2 and the locking mechanism 4 respectively. The reset member 41 typically has a force that drives the locking mechanism 4 to move to the locked position, which can improve the locking reliability and achieve a fast and automatic locking effect. Specifically, when the locking mechanism 4 moves from the locked position to the released position, it needs to overcome the reset force of the reset member 41. This can improve the stability of the air supply assembly 1 when locked. After the air supply assembly 1 is installed, the locking mechanism 4 can automatically return to the locked position. In conjunction with the foregoing, when the hook 105 and the slot 102 are engaged in the locked state, the force provided by the reset member 41 can also maintain the stability of the engagement between the hook 105 and the slot 102.
[0075] Combination Figure 7An extension plate 11c is provided at the end of the air supply frame 11 along the first direction. The extension plate 11c is opposite to the locking mechanism 4, and the extension plate 11c cooperates with the locking mechanism 4 to lock and release the air supply assembly 1. Specifically, when the air supply frame 11 is installed along the left and right directions and the air supply assembly 1 is installed along the front and back directions, the extension plate 11c can extend into the locking mechanism 4. The reset member 41 drives the locking mechanism 4 to move to the locking position, which can lock the extension and thus lock the air supply assembly 1. This simplifies the structure, and the extension is opposite to the stove body 2 along the front and back directions, occupying less space and facilitating space arrangement. The hook 105 can be provided on the extension plate 11c and extends along the third direction. When the extension moves along the front and back directions, the hook 105 can be inserted into or disengaged from the slot 102. More specifically, the hook 105 can include a head and a rod. The rod is connected to the extension plate 11c, and the head is constructed in a wedge shape to facilitate entry into the slot 102.
[0076] Combination Figure 11 and Figure 12 In some embodiments, the air supply frame 11 is constructed as a rectangular frame extending along a first direction. Specifically, the stove body 2 is generally constructed in a rectangular shape. Therefore, the rectangular shape of the air supply frame 11 is suitable for cooperating with the stove body 2, so that the air supply range can cover the area where the user uses the stove body 2. In addition, the rectangular air supply frame 11 is easy to install near the stove, which is beneficial for space arrangement. Furthermore, the driving member 3 is located on the outer side of the end of the air supply frame 11. The driving member 3 and the air supply frame 11 are opposite each other along the first direction, which helps to increase the arrangement space of the driving member 3 and makes the operation of the driving member 3 less likely to be affected.
[0077] In some embodiments, the stove body 2 integrates an air conditioning mechanism, which is connected to the air supply component 1. The air conditioning mechanism can adjust the air supply temperature, and the user can adjust the temperature according to actual needs, so that the air supply component 1 can blow out cold air or hot air, thereby improving the user's comfort.
[0078] Combination Figures 1 to 12The air supply frame 11 is configured to supply air in a third direction. The air guide plate 15 is rotatably connected to the air supply frame 11. The rotating component 13 includes a first connecting portion 51, and the driving component 3 includes a second connecting portion 52. The first connecting portion 51 and the second connecting portion 52 are adapted to dock in a third direction to enable the driving component 3 and the rotating component 13 to be connected in a transmission manner. The first connecting portion 51 and the second connecting portion 52 are also adapted to separate in a third direction. That is, the driving component 3 and the rotating component 13 can be connected in a transmission manner through the docking of the first connecting portion 51 and the second connecting portion 52. This simplifies the mating structure between the driving component 3 and the rotating component 13 and facilitates the assembly and disassembly of the driving component 3 and the rotating component 13. Specifically, the rotating component 13 is connected to the air supply frame 11. When the power of the driving component 3 is needed, the air supply frame 11 can be moved directly in the third direction so that the first connecting part 51 of the rotating component 13 can be connected with the second connecting part 52 of the driving component 3 to achieve power transmission. When disassembling the air supply frame 11, the air supply frame 11 can be moved in the front-back direction, and the first connecting part 51 of the rotating component 13 and the second connecting part 52 of the driving component 3 can be separated. This allows for the separate assembly and disassembly of the air supply frame 11 and the driving component 3, which is convenient for users to maintain and clean the air supply mechanism.
[0079] In some embodiments, the rotation center axis of the rotating member 13 extends in a direction perpendicular to a third direction, and the rotation center axis of the rotating member 13 and the rotation center axis of the second connecting part 52 are parallel or coincident with each other. The first connecting part 51 and the second connecting part 52 are configured as a coupling structure that can be separated along a third direction. In this way, when the driving member 3 and the rotating member 13 are connected in transmission, they can be firmly connected and rotate together to transmit motion and torque, so that the driving member 3 and the rotating member 13 can rotate together during the transmission of motion and power.
[0080] Combination Figure 6 and Figure 7In some embodiments, the first connecting portion 51 is configured as a rotating block with multiple mating grooves 520, and the multiple mating grooves 520 are spaced apart around the rotation center axis of the first connecting portion 51. A mating block is constructed on the second connecting portion 52, and the mating block is separably embedded in one of the multiple mating grooves 520 along a third direction. Alternatively, the second connecting portion 52 can be configured as a rotating block with multiple mating grooves 520, and the multiple mating grooves 520 are spaced apart around the rotation center axis of the first connecting portion 51. A mating block is constructed on the first connecting portion 51, and the mating block is separably embedded in one of the multiple mating grooves 520 along a third direction. That is, one of the first connecting portion 51 or the second connecting portion 52 is a rotating block and the other is a mating block. The mating block can be embedded in the mating groove 520 of the rotating block. Rotation of one of the mating block or the rotating block can drive the other to rotate, thereby realizing the transmission connection between the driving member 3 and the rotating member 13. The structure is simple and easy to construct. In addition, the rotating block is provided with multiple mating grooves 520 to facilitate the connection between the rotating block and the mating block. That is, after the rotating block rotates, it still has open mating grooves 520 that can be mated and connected with the mating block.
[0081] Combination Figure 7 In some embodiments, the mating groove 520 is configured as a V-shape, and the mating block is configured as a wedge shape adapted to the shape of the mating groove 520. The form of the two sides of the wedge converging in the same direction is suitable for mating with the V-shaped mating groove 520. The mating block is embedded in the opening of the mating groove 520 to close the opening end of the mating groove 520, which can construct an approximately triangular shape, which is beneficial to improve the structural strength and improve the stability of the mating.
[0082] In some embodiments, the rotating block is configured as a gear, with a mating groove 520 formed between each pair of adjacent teeth. The rotational center shaft of the gear is adapted to be connected to the rotational shaft of the drive member 3, and the tooth grooves are adapted to form the mating groove 520 and are readily available. When the rotating block is connected to the mating block, motion and power can be transmitted at a predetermined speed ratio, which helps to improve operational stability.
[0083] In some embodiments, the drive component 3 is located on the outer side of the end of the air supply frame 11, and the drive component 3 is opposite to the corresponding rotating component 13 along the first direction, which is beneficial to separating the drive component 3 from the air supply frame 11, increasing the arrangement space of the drive component 3, and the drive component 3 is not easily affected by external factors such as air supply or oil fumes during operation, which is beneficial to improving operational stability and durability.
[0084] In addition, in conjunction with the foregoing, the air supply assembly 1 also includes a guide vane 16. The connection method between the guide vane 16 and the corresponding drive structure is the same as the foregoing method. That is, the guide vane 16 and the corresponding drive structure are also detachably connected and driven by the first connecting part 51 and the second connecting part 52.
[0085] In addition, the air supply frame 11 is provided with a first drive motor and a second drive motor on the outer sides of both ends along the first direction to drive the air guide plate 15 and the blades (see Figure 5 (Driver 3 in the middle).
[0086] In the description of this invention, it should be understood that the terms "center", "width", "upper", "lower", "front", "rear", "left", "right", "inner", "outer", "axial", "circumferential", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.
[0087] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of that feature. In the description of this invention, "a plurality of" means at least two, such as two, three, etc., unless otherwise explicitly specified.
[0088] In this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," "linking," and "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components, unless otherwise explicitly limited. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.
[0089] In this invention, unless otherwise explicitly specified and limited, "above" or "below" the second feature can mean that the first feature is in direct contact with the second feature, or that the first feature is in indirect contact with the second feature through an intermediate medium. Furthermore, "above," "over," and "on top" of the second feature can mean that the first feature is directly above or diagonally above the second feature, or simply that the first feature is at a higher horizontal level than the second feature. "Below," "below," and "under" the second feature can mean that the first feature is directly below or diagonally below the second feature, or simply that the first feature is at a lower horizontal level than the second feature.
[0090] In the description of this specification, the references to terms such as "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., refer to specific features, structures, materials, or characteristics described in connection with that embodiment or example, which are included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of different embodiments or examples.
[0091] Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention. Those skilled in the art can make changes, modifications, substitutions and variations to the above embodiments within the scope of the present invention.
Claims
1. An air supply assembly, characterized in that, include: Air supply frame; A rotating component, which is rotatably connected to the air supply frame; A transmission component, wherein the transmission component is rotatably connected to the rotating component; An air guide plate, which is rotatably connected to the air supply frame and rotatably connected to the transmission component. The rotating component, the transmission component, and the air guide plate are connected to form a planar four-bar linkage. The air guide plate includes multiple air guide plates, each of which is connected to the same transmission member. The multiple air guide plates are driven by the transmission member to rotate synchronously. The transmission member includes a main body and multiple branches, each of which is connected to the main body. The main body is rotatably connected to the rotating member. Each of the multiple branches corresponds to a multiple air guide plate, and each branch is rotatably connected to its corresponding air guide plate.
2. The air supply assembly according to claim 1, characterized in that, The transmission component is integrally molded.
3. The air supply assembly according to claim 1, characterized in that, The air supply frame is provided with a first limiting structure, and the rotating component is provided with a second limiting structure. The first limiting structure and the second limiting structure cooperate to limit the rotation angle of the rotating component.
4. The air supply assembly according to claim 3, characterized in that, The first limiting structure is a limiting groove, the second limiting structure is a limiting slider, and the limiting slider is slidably embedded in the limiting groove.
5. The air supply assembly according to claim 1, characterized in that, The rotating component includes: An inner turntable is rotatably disposed inside the air supply frame; An outer turntable is located on the outside of the air supply frame and is fixedly connected to the inner turntable. The transmission component is eccentrically connected to the inner turntable, and the outer turntable is used to connect the drive component.
6. The air supply assembly according to claim 5, characterized in that, One of the inner turntable and the outer turntable is provided with a positioning pin and the other is provided with a positioning hole. The positioning pin is embedded in the positioning hole, and the inner turntable and the outer turntable are connected by fasteners.
7. The air supply assembly according to claim 5, characterized in that, The air supply frame is provided with mounting holes, and the inner turntable is provided with a stepped portion and a rotating shaft portion. The stepped portion is provided on the inner turntable, and the rotating shaft portion is provided on the stepped portion and is rotatably embedded in the mounting holes. The periphery of the stepped portion is opposite to the inner side surface of the air supply frame.
8. The air supply assembly according to any one of claims 1-7, characterized in that, The air supply frame is constructed as a rectangular frame extending along a first direction. The air guide plate extends along the first direction and is rotatably connected to both ends of the air supply frame. The rotating member is rotatably disposed at the end of the air supply frame, and the rotation center axis of the rotating member is parallel to the first direction.
9. An integrated stove, characterized in that, include: stove body; An air supply assembly is provided on the stove body, and the air supply assembly is the air supply assembly according to any one of claims 1-8; A driving component is disposed on the stove body and is connected to the rotating component for transmission.
10. The integrated stove according to claim 9, characterized in that, The air supply assembly is configured to supply air in a third direction and is detachably connected to the cooktop in the third direction, and the rotating component is detachably connected to the driving component in the third direction. Wherein, the third direction is perpendicular to the rotation center axis of the rotating component.
11. The integrated stove according to claim 9, characterized in that, The air supply frame is configured as a rectangular frame extending along a first direction, and the driving member is located on the outer side of the end of the air supply frame, and the driving member and the air supply frame are opposite each other along the first direction.
12. The integrated stove according to claim 9, characterized in that, The stove body integrates an air conditioning mechanism, which is connected to the air supply component.