Shock-absorbing base and household appliances
By using the clamping design of the limiting ribs and the flange, and the cooperation of the inclined surface, the problem of the shock-absorbing pad loosening is solved, and the stability and visual effect are improved, ensuring the safety and user experience of the shock-absorbing pad.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- GREE ELECTRIC APPLIANCE INC OF ZHUHAI
- Filing Date
- 2025-08-14
- Publication Date
- 2026-07-03
AI Technical Summary
The shock-absorbing pads in the existing technology are prone to loosening due to vibration or external force, which requires users to manually reset them frequently, affecting the user experience.
The design employs limiting ribs and flanges to mechanically fix the shock-absorbing pad through the clamping action of the outer shell and the base assembly. The stability and visual effect are improved by the use of inclined surfaces, annular ribs, and grooves.
It effectively prevents the shock-absorbing pads from loosening, improves the user experience, enhances the overall structural stability and appearance quality, and ensures the safety of the shock-absorbing pad material.
Smart Images

Figure CN224453528U_ABST
Abstract
Description
Technical Field
[0001] This application relates to the field of household appliance technology, specifically to a shock-absorbing base and a household appliance. Background Technology
[0002] Currently, most food processing appliances on the market, such as blenders and soy milk makers, have shock-absorbing pads at the bottom to reduce vibrations on the countertop during operation. These pads are typically either directly embedded in the bottom of the appliance or glued to it.
[0003] However, after prolonged use, the shock-absorbing pads are prone to loosening due to vibration or external force, requiring users to manually reset them frequently, which seriously affects the user experience. Utility Model Content
[0004] In view of this, this application provides a shock-absorbing base and a household appliance to solve the technical problem that shock-absorbing pads in the prior art are prone to loosening due to vibration or external force.
[0005] In a first aspect, this application provides a shock-absorbing base, which includes:
[0006] The base assembly is provided with a mounting groove; a limiting part is provided on the side wall of the mounting groove;
[0007] A shock-absorbing pad is provided on the mounting groove; the shock-absorbing pad has at least one flange on its outer periphery extending to the top of the limiting part;
[0008] The outer shell is provided with limiting ribs; the limiting ribs are provided in correspondence with the flanges.
[0009] After the outer shell is installed on the base assembly, the limiting ribs and the limiting part clamp the flange.
[0010] Beneficial effects: This embodiment features a flange that, after the outer shell and base assembly are assembled, precisely clamps the flange of the shock-absorbing pad. This interlocking of structural components mechanically secures the shock-absorbing pad, preventing it from loosening due to vibration or external forces. This eliminates the need for frequent manual repositioning by the user, improving the user experience. Furthermore, since the flange is positioned precisely between the outer shell and base assembly, it disperses the impact forces generated between them, further enhancing the overall structural stability.
[0011] In one alternative embodiment, the flange is continuously arranged along the outer periphery of the shock-absorbing pad to form an annular boss.
[0012] Beneficial effects: In this embodiment, the flange is set as an annular boss, which allows for optimization of vibration frequency and stress in all directions during operation of the entire device. This effectively disperses the impact forces generated between the outer shell and the base assembly in various directions, further improving the overall structural stability. Furthermore, it effectively limits the displacement of the damping pads caused by vibration in all directions, preventing the flanges from loosening from their original positions due to vibration or external forces.
[0013] In one optional embodiment, the limiting rib is provided with a first inclined surface on the side near the shock-absorbing pad, and the shock-absorbing pad is provided with a second inclined surface on the outer circumferential side, the second inclined surface being provided in correspondence with the first inclined surface;
[0014] When the limiting rib and the limiting part clamp the flange, the first inclined surface and the second inclined surface are in contact.
[0015] Beneficial effects: Compared to the traditional straight-face mating method, this embodiment adopts an angled mating design. When viewed from above, the reflection of light on the angled surface effectively conceals any tiny gaps, achieving a visually "seamless" effect. The visible gap width is reduced by approximately 70% compared to traditional straight-face mating, significantly improving the product's appearance.
[0016] In one alternative implementation, the top of the flange and the top of the damping pad are connected by a second ramp transition.
[0017] Beneficial effects: In this embodiment, the top of the flange and the top of the shock-absorbing pad are connected by a second inclined surface. Since the force between the outer shell and the base is in the vertical direction, the second inclined surface can increase the contact area between the outer shell and the shock-absorbing pad compared with a right angle transition, thereby improving the stability between the two and preventing the shock-absorbing pad from loosening from its original position due to vibration or external force.
[0018] In one optional embodiment, the first inclined surface is provided with a first limiting member on the side near the second inclined surface, and the second inclined surface is provided with a corresponding second limiting member on the side near the first inclined surface.
[0019] Beneficial effects: In this embodiment, a first limiting member and a second limiting member are provided between the first inclined surface and the second inclined surface, which can further improve the stability between the outer shell and the shock-absorbing pad, making the shock-absorbing pad more stable in the original installation position.
[0020] In one alternative embodiment, the first limiting member is an annular protrusion arranged circumferentially in the horizontal direction, and the second limiting member is an annular groove arranged circumferentially in the horizontal direction. After the outer shell is installed on the base assembly, the annular protrusion is embedded in the annular groove.
[0021] Beneficial effects: In this embodiment, the annular ribs and annular grooves are arranged in a horizontal direction. Since the force between the outer shell and the base is in a vertical direction, compared with other arrangement directions, the limiting ability between the annular ribs and annular grooves can be maximized, further improving the stability between the outer shell and the shock-absorbing pad.
[0022] In one optional embodiment, multiple annular ribs are spaced apart, and the gap between two adjacent annular ribs is the same, and annular grooves are provided corresponding to the annular ribs.
[0023] Beneficial effects: In this embodiment, the annular ribs are spaced apart, which increases the fixing area of the annular ribs on the shock-absorbing pad, thereby improving the stability between the shell and the shock-absorbing pad. On the other hand, the annular ribs can make the force evenly distributed around the shock-absorbing pad, avoiding positional displacement caused by uneven force distribution, and thus preventing the shock-absorbing pad from loosening from its original position.
[0024] In one alternative embodiment, the outer casing has a through hole, and the inner wall of the through hole is provided with a limiting rib. After the outer casing is installed on the base assembly, the top of the shock-absorbing pad extends outward from the through hole.
[0025] Beneficial effects: In this embodiment, the top of the shock-absorbing pad extends outward from the through hole. When the functional equipment is installed on the shock-absorbing base, the edge of the functional equipment can be prevented from directly contacting the shock-absorbing base. By utilizing the buffering effect of the shock-absorbing pad, the vibration and stress on the edge of the functional equipment and the shock-absorbing base can be buffered, effectively dispersing the impact force generated between the shell and the base assembly in various directions, and further improving the stability of the overall structure.
[0026] In one alternative implementation, the shock-absorbing pad is made of TPE material.
[0027] Beneficial effects: In this embodiment, the shock-absorbing pad is made of TPE material. TPE material is non-toxic and odorless, and has passed strict food contact material safety tests. It fully complies with food-grade safety standards, ensuring that the functional equipment will not contaminate food during the food processing process, thus protecting the health and safety of users.
[0028] Secondly, this application provides a household appliance, which includes: a functional device and a shock-absorbing base as described in any of the above embodiments, wherein the functional device cooperates with the shock-absorbing base. Attached Figure Description
[0029] To more clearly illustrate the technical solutions in the specific embodiments of this application or the prior art, the drawings used in the description of the specific embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this application. For those skilled in the art, other drawings can be obtained from these drawings without creative effort.
[0030] Figure 1 This is a cross-sectional view of the household appliance as a whole in this application;
[0031] Figure 2 for Figure 1 A magnified view of part A in the middle;
[0032] Figure 3 This is a top view of the shock-absorbing base in this application;
[0033] Figure 4 This is a top view of the outer casing in this application;
[0034] Figure 5 This is a schematic diagram of the shock-absorbing pad in this application.
[0035] Explanation of reference numerals in the attached figures:
[0036] 1. Base assembly; 11. Mounting slot; 12. Limiting part;
[0037] 2. Shock-absorbing pad; 21. Flange; 22. Second inclined surface;
[0038] 3. Outer shell; 31. Limiting rib; 32. First inclined surface; 33. Through hole;
[0039] 4. Functional equipment. Detailed Implementation
[0040] To make the objectives, technical solutions, and advantages of the embodiments of this application clearer, the technical solutions of the embodiments of this application will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this application, not all embodiments. Based on the embodiments of this application, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of this application.
[0041] In the description of this application, it should be noted that the terms "inner," "upper," "outer," "lower," "underneath," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, and are only for the convenience of describing this application 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, and therefore should not be construed as a limitation on this application. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
[0042] In the description of this application, it should be noted that, unless otherwise expressly specified and limited, the terms "installation," "connection," and "communication" should be interpreted broadly. For example, they can refer to fixed communication, detachable communication, or integral communication; they can refer to mechanical communication or electrical communication; they can refer to direct connection or indirect connection through an intermediate medium; they can refer to communication within two components; and they can refer to wireless communication or wired communication. Those skilled in the art can understand the specific meaning of the above terms in this application based on the specific circumstances.
[0043] Currently, most food processing appliances on the market, such as blenders and soy milk makers, typically have shock-absorbing pads (2) at the bottom to reduce vibrations on the countertop during operation. These pads are usually either directly embedded in the bottom of the appliance or glued to it. However, after prolonged use, these pads are prone to loosening due to vibration or external forces, requiring frequent manual repositioning and significantly impacting the user experience.
[0044] In view of this, this application provides a shock-absorbing base and a household appliance to solve the technical problem that the shock-absorbing pad 2 in the prior art is easily loosened due to vibration or external force.
[0045] The following is combined Figures 1 to 5 This describes an embodiment of the present application.
[0046] like Figures 1 to 5 As shown in the embodiments of this application, in one aspect, this application provides a shock-absorbing base, which includes a base assembly 1, a shock-absorbing pad 2, and a housing 3.
[0047] Specifically, in this embodiment, the base assembly 1 is provided with a mounting groove 11, and a limiting part 12 is provided on the side wall of the mounting groove 11. The base assembly 1 is a supporting frame of the assembly structure and can be made of high-strength engineering plastic or metal material. At the parts that mate with the shock-absorbing pad 2 and the outer shell 3, the outer shell 3 is provided with corresponding mounting grooves 11 and limiting parts 12. The mounting groove 11 is used to install the shock-absorbing pad 2, and the limiting part 12 is used to fix the shock-absorbing pad 2 after mating with the outer shell 3. It should be noted that in this embodiment, the size of the mounting groove 11 matches the shape of the shock-absorbing pad 2 to ensure that the shock-absorbing pad 2 can be accurately installed in place.
[0048] Furthermore, in this embodiment, the shock-absorbing pad 2 is disposed on the mounting groove 11, and the shock-absorbing pad 2 has at least one flange 21 extending to the top of the limiting part 12 on its outer periphery. As the core shock-absorbing component of the entire assembly structure, the structural shape of the shock-absorbing pad 2 corresponds to the mounting groove 11. In this embodiment, a circular structure is used as an example. Furthermore, it is necessary to ensure that the shock-absorbing pad 2 has good elasticity and temperature resistance; for example, silicone or modified rubber can be used.
[0049] Of course, this embodiment is merely an example of the material of the shock-absorbing pad 2, but it does not limit the scope of the invention. Those skilled in the art can make changes according to the actual situation, as long as the same technical effect can be achieved.
[0050] Furthermore, in this embodiment, multiple flanges 21 can be spaced apart or continuously arranged on the outer periphery of the shock-absorbing pad 2. When spaced apart, those skilled in the art can change the length and number of flanges 21 according to actual conditions. Of course, this embodiment does not limit this, as long as the same technical effect can be achieved.
[0051] Furthermore, in this embodiment, the outer shell 3 is provided with a limiting rib 31, which is correspondingly provided with the flange 21. After the outer shell 3 is installed on the base assembly 1, the limiting rib 31 and the limiting part 12 clamp the flange 21.
[0052] Specifically, the outer shell 3 not only enhances the overall appearance of the shock-absorbing base but is also a key component for achieving the limiting function. Its surface is finely treated and can be customized with different textures or colors to suit the product design style. On the inner side that mates with the shock-absorbing pad 2, the outer shell 3 has a circular limiting rib 31. The shape formed by the limiting rib 31 and the limiting part 12 complements the flange 21 of the shock-absorbing pad 2, allowing for precise insertion between the limiting rib 31 and the limiting part 12 during assembly, creating a bidirectional limiting effect similar to a mortise and tenon joint.
[0053] Regarding the installation method of the outer shell 3 and the base assembly 1, it can be fixed by a snap-fit or slot-fit method, a screw or screw hole method, or a magnetic attachment method. Of course, this embodiment is not limited to this method, as long as the same technical effect is achieved.
[0054] In actual assembly, the assembly sequence is as follows: first, install the shock-absorbing pad 2 onto the base assembly 1 from top to bottom, and then install the outer shell 3 from top to bottom, so that the outer shell 3 presses down on the flange 21 of the shock-absorbing pad 2. Finally, fix the base assembly 1 and the outer shell 3. The force generated by the fixing of the base assembly 1 and the outer shell 3 can firmly press down the shock-absorbing pad 2, so that the shock-absorbing pad 2 will not loosen due to vibration or external force after long-term use.
[0055] With this configuration, the flange 21 in this embodiment allows the outer shell 3 and the base assembly 1 to clamp the flange 21 of the shock-absorbing pad 2, thereby mechanically fixing the shock-absorbing pad 2 by utilizing the interlocking of the structural components. This prevents the shock-absorbing pad 2 from loosening due to vibration or external force, eliminating the need for frequent manual repositioning by the user and improving the user experience. Furthermore, since the flange 21 is positioned precisely between the outer shell 3 and the base assembly 1, it can disperse the impact force generated between the outer shell 3 and the base assembly 1, further enhancing the overall structural stability.
[0056] It is important to note that the shock-absorbing base in this embodiment consists of a shock-absorbing pad 2, a housing 3, and a base assembly 1. These three components work together as a coordinated system through a precise structural design. The shock-absorbing pad 2, as the core component for shock absorption, utilizes the cooperation between the flange 21 and the limiting rib 31 to achieve both shock absorption and fixation. The base assembly 1 provides a support frame for the entire assembly structure and, after being fixed to the housing 3, forms a complete mechanical transmission path. This multi-component collaborative mechanism allows each component to perform its maximum function while simultaneously constraining each other, ensuring the stability and reliability of the overall structure.
[0057] Furthermore, in an optional embodiment, the flange 21 is continuously arranged along the outer periphery of the shock-absorbing pad 2 to form an annular boss. In this embodiment, the shock-absorbing pad 2 adopts a circular structure design, with the flange 21 encircling the outer periphery of the shock-absorbing pad 2 to form an annular boss. After mechanical calculations and multiple experimental verifications, the height, width, and curvature of the annular boss are matched with the functional device 4 that is actually placed on the base assembly 1 for operation, so that the annular boss can optimize the vibration frequency and stress conditions generated by the functional device 4 during operation.
[0058] In this embodiment, the height of the flange 21 can be designed within a certain reasonable range to improve the effect of the flange 21. For example, the height of the flange 21 can be 1.5mm-2mm, which can provide sufficient limiting force without affecting the assembly accuracy due to the flange 21 being too high.
[0059] With this configuration, the flange 21 is set as an annular boss in this embodiment, which allows for optimization of vibration frequency and stress in all directions during operation of the device. This effectively disperses the impact forces generated between the outer shell 3 and the base assembly 1 in all directions, further improving the overall structural stability. Furthermore, it effectively limits the displacement of the damping pad 2 caused by vibration in all directions, preventing the flange 21 from loosening from its original position due to vibration or external forces.
[0060] Furthermore, in an optional embodiment, the limiting rib 31 is provided with a first inclined surface 32 on the side near the shock-absorbing pad 2, and the shock-absorbing pad 2 is provided with a second inclined surface 22 on its outer circumferential side, the second inclined surface 22 corresponding to the first inclined surface 32. Regarding the location of the second inclined surface 22, for example, it can be located on the top of the shock-absorbing pad 2, on the side of the shock-absorbing pad 2, or on the side of the flange 21. Of course, this embodiment is merely an example of the location of the second inclined surface 22, and is not intended to limit it. Those skilled in the art can modify it according to actual conditions, as long as the same technical effect is achieved.
[0061] Furthermore, when the limiting rib 31 and the limiting part 12 clamp the flange 21, the first inclined surface 32 and the second inclined surface 22 are in contact.
[0062] In this embodiment, the presence of the bevel makes the cross-sectional shape of the flange 21 trapezoidal, wider at the top and narrower at the bottom along the vertical direction. This facilitates its cooperation with the limiting rib 31 of the outer shell 3. The angle of the bevel can be 45°. This bevel design is key to achieving a visually seamless effect.
[0063] Compared to the traditional straight-face mating method, this embodiment adopts an angled mating design. When viewed from above, the reflection of light on the angled surface effectively conceals any tiny gaps, achieving a visually "seamless" effect. The visible gap width is reduced by approximately 70% compared to a traditional straight-face mating, significantly improving the product's appearance.
[0064] Furthermore, in an alternative embodiment, the top of the flange 21 is transitionally connected to the top of the damping pad 2 via a second inclined surface 22.
[0065] With this configuration, the top of the flange 21 and the top of the shock-absorbing pad 2 are connected by a second inclined surface 22. Since the force between the outer shell 3 and the base is in the vertical direction, the second inclined surface 22 can increase the contact area between the outer shell 3 and the shock-absorbing pad 2 compared to a right angle transition, thereby improving the stability between the two and preventing the flange 21 from loosening from its original position due to vibration or external force.
[0066] Furthermore, in an optional embodiment, the first inclined surface 32 is provided with a first limiting member on the side near the second inclined surface 22, and the second inclined surface 22 is correspondingly provided with a second limiting member on the side near the first inclined surface 32. The first and second limiting members can be mutually cooperating protrusions and grooves, mutually cooperating wavy stripes, or mutually cooperating magnetic elements. Of course, this embodiment is merely illustrative and is not intended to limit the scope. Those skilled in the art can make changes according to actual circumstances, as long as the same technical effect is achieved.
[0067] With this configuration, the first limiting member and the second limiting member are provided between the first inclined surface 32 and the second inclined surface 22 in this embodiment, which can further improve the stability between the outer shell 3 and the shock-absorbing pad 2, making the shock-absorbing pad 2 more stable in the original installation position.
[0068] Furthermore, in an optional embodiment, the first limiting member is an annular protrusion arranged circumferentially in the horizontal direction, and the second limiting member is an annular groove arranged circumferentially in the horizontal direction. After the outer shell 3 is installed on the base assembly 1, the annular protrusion is embedded in the annular groove.
[0069] With this configuration, the annular ribs and annular grooves are arranged horizontally in this embodiment. Since the force between the outer shell 3 and the base is vertical, the limiting ability between the annular ribs and annular grooves can be maximized compared to other arrangement directions, thereby further improving the stability between the outer shell 3 and the shock-absorbing pad 2.
[0070] Furthermore, in an optional embodiment, the plurality of annular ribs are concentric ring structures, spaced apart from each other, with the same gap between adjacent annular ribs. Annular grooves are correspondingly provided with the annular ribs. For example, the number of annular ribs and annular grooves can be one, two, three, etc. Of course, this embodiment is merely an example illustrating the number of annular ribs and annular grooves, but it is not limiting. Those skilled in the art can modify them according to actual circumstances, as long as the same technical effect is achieved.
[0071] In this configuration, the annular ribs are spaced apart, which increases the fixing area of the annular ribs on the damping pad 2, thereby improving the stability between the outer shell 3 and the damping pad 2. Furthermore, the annular ribs ensure even force distribution around the damping pad 2, preventing displacement due to uneven force and thus preventing the damping pad 2 from detaching from its original position. Simultaneously, the multiple annular ribs and grooves significantly increase the contact area between the limiting pressure rib 31 and the damping pad 2, increasing the friction between them and further enhancing the stability between the outer shell 3 and the damping pad 2.
[0072] Furthermore, in an optional embodiment, the outer shell 3 is provided with a through hole 33, and the inner wall of the through hole 33 is provided with a limiting rib 31. After the outer shell 3 is installed on the base assembly 1, the top of the shock-absorbing pad 2 extends outward from the through hole 33.
[0073] With this configuration, the top of the shock-absorbing pad 2 extends outward from the through hole 33 in this embodiment. When the functional device 4 is installed on the shock-absorbing base, the edge of the functional device 4 can be prevented from directly contacting the shock-absorbing base. By utilizing the buffering effect of the shock-absorbing pad 2, the vibration and stress on the edge of the functional device 4 and the shock-absorbing base can be buffered, effectively dispersing the impact force generated between the outer shell 3 and the base assembly 1 in various directions, and further improving the stability of the overall structure.
[0074] Furthermore, in an optional embodiment, the shock-absorbing pad 2 is made of TPE material. When the functional device 4 is a food processing device such as a soymilk maker or a blender, the material selection takes into account the usage environment and functional requirements of the functional device 4. The shock-absorbing pad 2 is made of TPE material. TPE material is non-toxic and odorless, has passed strict food contact material safety testing, and fully complies with food-grade safety standards, ensuring that it will not contaminate food during food processing and protecting the health and safety of users. In addition, TPE material can withstand a certain range of temperature changes, being resistant to both high and low temperatures. In various working environments where the functional device 4 heats food to temperatures above 100°C or cools drinks to temperatures below 0°C, the shock-absorbing pad 2 can maintain stable physical properties and mechanical strength, without hardening, softening, or deformation due to temperature changes, ensuring the long-term stability of the shock absorption effect. Furthermore, TPE material itself has excellent elasticity and flexibility, which can effectively absorb and buffer the vibration energy generated by the functional device 4 during operation, significantly reducing the energy of vibration transmitted to the outer shell 3, thereby reducing the vibration and noise of the entire machine and improving the user experience.
[0075] With this configuration, the shock-absorbing pad 2 in this embodiment is made of TPE material. TPE material is non-toxic and odorless, and has passed strict food contact material safety tests, fully complying with food-grade safety standards. This ensures that the functional device 4 will not contaminate the food during the food processing process, thus protecting the health and safety of users.
[0076] The overall assembly process in this embodiment adopts a top-down sequence, and precise step control ensures the correct installation and functional realization of each component. The specific assembly process is as follows:
[0077] The first step is to install the shock-absorbing pad 2. First, vertically insert the shock-absorbing pad 2 into the mounting slot 11 of the base assembly 1 from above. Because the shape of the shock-absorbing pad 2 precisely matches the mounting slot 11, during insertion, the flange 21 of the shock-absorbing pad 2 will generate a certain amount of friction with the edge of the mounting slot 11. However, this friction is designed within a reasonable range, ensuring that the shock-absorbing pad 2 will not easily fall off while facilitating installation. During installation, pay attention to the orientation of the shock-absorbing pad 2, ensuring that the flange 21 is completely inside the mounting slot 11 and remains horizontal, avoiding tilting.
[0078] The second step is to install the outer casing 3. After the shock-absorbing pad 2 is installed in place, the outer casing 3 is slowly lowered from above, covering the shock-absorbing pad 2. At this time, the limiting rib 31 of the outer casing 3 will begin to contact the flange 21 of the shock-absorbing pad 2. Since both adopt a trapezoidal cross-section and inclined surface design, during the process of lowering the outer casing 3, the limiting rib 31 directly clamps and fixes the flange 21 of the shock-absorbing pad 2. This process does not require additional positioning tools; precise alignment can be achieved solely through the cooperation of the structures themselves.
[0079] The third step is to secure the outer casing 3. Once the outer casing 3 is fully lowered and attached to the base assembly 1, screws can be used to connect and secure the two through the fixing holes on the outer casing 3 and the base assembly 1. During the tightening of the screws, the outer casing 3 will exert downward pressure on the shock-absorbing pad 2. This pressure is transmitted to the shock-absorbing pad 2 through the cooperation of the limiting rib 31 and the flange 21, thereby firmly fixing the shock-absorbing pad 2 in the outer casing 3.
[0080] Step 4: Check the assembly effect: After assembly, the overall structure needs to be checked. First, observe whether the gaps between the outer shells 3 are uniform and whether there are obvious height differences; then gently shake the shock-absorbing pad 2 to check for any looseness. If uneven gaps or loose shock-absorbing pad 2 are found, the assembly steps need to be checked again, and the problem needs to be eliminated before fixing.
[0081] Secondly, this application provides a household appliance comprising: a functional device 4 and a shock-absorbing base as described in any of the above embodiments, wherein the functional device 4 cooperates with the shock-absorbing base. The functional device 4 may be a juicer, blender, food processor, grinder, high-speed blender, or soy milk maker.
[0082] Although embodiments of this application have been described in conjunction with the accompanying drawings, those skilled in the art can make various modifications and variations without departing from the spirit and scope of this application, and all such modifications and variations fall within the scope defined by the appended claims.
Claims
1. A shock mount, characterized in that, include: The base assembly (1) is provided with a mounting groove (11); a limiting part (12) is provided on the side wall of the mounting groove (11); A shock-absorbing pad (2) is disposed on the mounting groove (11); the shock-absorbing pad (2) has at least one flange (21) on its outer periphery extending to the top of the limiting part (12); The outer shell (3) is provided with a limiting rib (31); the limiting rib (31) is provided correspondingly to the flange (21); After the outer shell (3) is installed on the base assembly (1), the limiting rib (31) and the limiting part (12) clamp the flange (21).
2. The shock mount of claim 1, wherein, The flange (21) is continuously arranged along the outer periphery of the shock-absorbing pad (2) to form an annular boss.
3. The shock mount of claim 2, wherein, The limiting rib (31) has a first inclined surface (32) on the side close to the shock-absorbing pad (2), and the shock-absorbing pad (2) has a second inclined surface (22) on the outer circumferential side, and the second inclined surface (22) is corresponding to the first inclined surface (32); When the limiting rib (31) and the limiting part (12) clamp the flange (21), the first inclined surface (32) and the second inclined surface (22) are in contact.
4. The shock mount of claim 3, wherein, The top of the flange (21) and the top of the shock-absorbing pad (2) are connected by the second inclined surface (22).
5. A vibration isolation mount according to claim 3 or 4, characterised in that, The first inclined surface (32) is provided with a first limiting member on the side near the second inclined surface (22), and the second inclined surface (22) is provided with a second limiting member on the side near the first inclined surface (32).
6. The shock mount of claim 5, wherein, The first limiting member is an annular protrusion arranged circumferentially in the horizontal direction, and the second limiting member is an annular groove arranged circumferentially in the horizontal direction. After the outer shell (3) is installed on the base assembly (1), the annular protrusion is embedded in the annular groove.
7. The shock mount of claim 6, wherein, The annular ribs are spaced apart, and the gap between two adjacent annular ribs is the same. The annular grooves are correspondingly arranged with respect to the annular ribs.
8. A vibration isolation mount according to any one of claims 1 to 4, characterised in that, The outer shell (3) has a through hole (33), and the inner wall of the through hole (33) is provided with the limiting pressure rib (31). After the outer shell (3) is installed on the base assembly (1), the top of the shock-absorbing pad (2) extends outward from the through hole (33).
9. A vibration isolation mount according to any one of claims 1 to 4, characterised in that, The shock-absorbing pad (2) is made of TPE material.
10. A household appliance, characterized in that, include: The functional device (4) and the shock-absorbing base as described in any one of claims 1 to 9, wherein the functional device (4) cooperates with the shock-absorbing base.