RU188005U1 - REMOVABLE BLENDER - Google Patents

Abstract

A utility model relates to a blender (10) for mixing ingredients. The blender (10) contains a base (11) containing a heating unit (12), a container (13) for containing the ingredients. Capacity (13) contains the lower part (14), detachable manually. The lower part (14) contains a lower plate (15) for contact with the heating unit (12). The lower part (14) also contains a blade assembly (16) passing through the lower plate (15), the blade assembly (16) having a first end (17) extending into the container (13) and containing at least one blade (18) and a second end (19) facing the base (11) and comprising a connecting element (20) for receiving a rotational force from the base (11). The lower part (14) also comprises a gripping element (21) surrounding the lower plate (15) for manually gripping and detaching the lower part (14), the gripping element (21) extending downward at least partially along the connecting element (20).

Description

The technical field to which the utility model relates.

A utility model relates to a blender for mixing ingredients.

The utility model can be used in the field of mixing food products, in particular in blenders for kitchen devices.

Utility Model Background

Blenders are kitchen appliances designed to mix food ingredients, such as fruits, milk, and ice, in liquids. Blenders generally consist of a base having a vertically located powerful AC motor with a first connection, and a cylindrical jug located directly above the base. The jug has a rotating blade assembly at the bottom with a second joint driven by the first joint.

Known blenders containing a means for heating the ingredients in a jug. The first embodiment of this type of blender contains a jug made of metal, a heating element integrated in the jug, and an electrical connection between the base and the jug to power the heating element. Another less popular embodiment of this type of blender includes a jug made of glass and a heating element located at the base. The heating element heats the bottom of the jug by means of thermal conductivity, and therefore, the electrical connection is not located between the jug and the base. This latter type of blender has the advantage of providing full transparency of the jug and a sense of quality for the user and, in addition, allows washing the jug in the machine, since the jug does not have an electrical connection.

In this latter type of blender, it may be desirable to remove the blade assembly for separate cleaning. However, such work may be unsafe for the user. If the user disconnects the blade assembly while the blade assembly is still hot due to heating by the heating element, the user may burn himself.

Purpose and brief description of utility model

The purpose of the utility model is to create a blender that reduces and / or eliminates one or more of the above problems.

The technical result is to increase user safety when using a blender by eliminating burns by the user.

The utility model is determined by the independent claims of the utility model. The dependent points of the utility model determine preferred embodiments.

For this purpose, a blender for mixing ingredients in accordance with a utility model contains:

- a base containing a heating unit,

- a container for containing ingredients, and the container contains a lower part, detachable manually, and the lower part contains:

- bottom plate for contact with the heating unit,

a blade assembly passing through the bottom plate, the blade assembly having a first end extending into the container and containing at least one blade, and a second end facing the base and containing a connecting member for receiving a rotational force from the base,

a gripping element surrounding the bottom plate for manually gripping and detaching the bottom, the gripping element extending down at least partially along the connecting element.

The aforementioned elements help to prevent scratching or damage to the bottom plate as a result of repeated use of the blender and, therefore, maintain good thermal conductivity of the bottom plate.

Preferably, the gripping element extends beyond the connecting element. This further prevents scratching and damage to the bottom plate.

Preferably, the gripping element forms mainly an annular tape or perimeter wall. This shape of the gripping element forms a large gripping area for the user and therefore facilitates the detachment of the bottom plate.

Preferably, the gripping element is made of heat-resistant material. Therefore, the gripping element can withstand high temperatures and not be damaged when the bottom plate is heated. Preferably, the gripping element is made of a material with low thermal conductivity or thermal insulation material. This prevents the user from getting burned when disconnecting the bottom plate if the temperature of the bottom plate is still high.

Preferably, the gripping element is made of plastic. Consequently, the gripping element has elastic properties that ensure accurate installation between the gripping element and the container and, therefore, an improved connection between the gripping element and the tank.

Preferably, the gripping element comprises at least one rod-like element or finger grip. This provides a reliable grip of the gripping element by the user.

Preferably, the gripping element comprises at least one protrusion. This provides a reliable grip of the gripping element by the user, in particular if the gripping element is tape-shaped or has the shape of a perimeter wall. In the case in which the gripping element comprises at least one rod-shaped element, protrusions are formed by rounding off the rods.

Preferably, the container comprises a lower region and a first annular protrusion extending around the lower region, the first annular protrusion comprising a thread configured to interact with an external thread formed in the lower part to detach the lower part from the vessel. This ensures that the bottom is easily detached from the tank. Preferably, an external thread is formed on the wall of the gripping element.

Preferably, the first annular protrusion is made of plastic. Therefore, the first annular protrusion has elastic properties that provide a good fit between the gripping element and the first annular protrusion and, therefore, an improved connection between the gripping element and the first annular protrusion.

Preferably, the container comprises a second annular protrusion surrounding the first annular protrusion, and the gasket is located between the second annular protrusion and the side wall of the container. This prevents damage to the second annular protrusion during the life of the blender.

Preferably, the lower part comprises a sealing element located between the lower plate and the container. This ensures good sealing of the container when securing the lower part to the container and prevents leakage of food ingredients and liquid into the container on the outside of the container.

Preferably, the gripping element extends upwardly around the sealing element, so that the sealing element is held onto the gripping element when the lower part is detached from the container. This ensures that the sealing element does not fall down when the lower part is disconnected from the container.

Preferably, when the internal thread engages with the external thread, the sealing element is held tightly in place between the bottom plate and the container. This additionally provides a good container seal.

Detailed explanations and other aspects of the utility model will be given below.

Brief Description of the Drawings

Specific aspects of the utility model will be explained with reference to the embodiments described below and discussed in conjunction with the drawings, in which like parts or sub-steps are indicated in the same way.

figa is a perspective view of a blender in accordance with a utility model;

figv is a perspective view of a blender, as shown in figure 1, and the container is removed from the base;

figs is a perspective view of the base of the blender, as shown in figure 1;

FIG. 1D is another perspective view of a blender, as shown in FIG. 1, in which, in particular, the detachable lower part of the container is visible;

figa is a perspective view in section of a jug and a node of the annular protrusion of the blender in accordance with a utility model;

figv is a view of a part of the jug and the node of the annular protrusion, as shown in figa;

figure 3 is a perspective view of the detachable lower part of the blender in accordance with the utility model;

4 is a perspective view with a spatial separation of the elements of the capacity of the blender in accordance with the utility model;

5 is a vertical sectional view of part of a blender in accordance with a utility model;

6 is a perspective view from below of the sealing element of the blender in accordance with the utility model;

figa is a top view of the detachable lower part and the heating unit of the blender in accordance with the utility model;

figv is a vertical sectional view of the detachable lower part and the heating unit of the blender in accordance with the utility model; and

figa, figv, figa, figv - different types of heating unit of the blender in accordance with the utility model.

Detailed description of utility model

On figa-1D depicts a blender 10 for mixing food ingredients in accordance with a utility model. The blender 10 described herein is, for example, a programmable blender for cooking.

In the description, terms such as “up”, “down”, “horizontal”, “vertical”, “lower part”, “upper part”, “upper”, “lower” and so on refer to the orientation of blender 10, as shown figure 1 of the accompanying drawings.

Blender 10 contains:

- base 11 containing a heating unit 12,

- a container 13 for containing ingredients, and the container 13 contains a lower part 14, detachable manually, and the lower part 14 contains

- bottom plate 15 for contact with the heating unit 12,

- the node 16 of the blade passing through the lower plate 15, and the node 16 of the blade has a first end 17 extending into the container 13 and containing at least one blade 18, and a second end 19 facing the base 11 and containing a connecting element 20 for receiving a rotary efforts from base 11,

a gripping element 21 surrounding the lower plate 15 for manually gripping and detaching the lower part 14, the gripping element 21 extending down at least partially along the connecting element 20.

The heating unit 12 has a heating plate 22 for heat transfer by the heat conductivity of the detachable lower part 14. The base 11 includes a temperature sensor 23 for detecting the temperature of the lower part 14 of the container 13, the temperature sensor 23 passing through the heating plate 22.

The container 13 or the jug assembly 13 is adapted to be fixed to the base 11. Preferably, the jug assembly 13 comprises a jug 24 and an annular protrusion assembly 25 or a skirt 25. The jug 24 is generally cylindrical. The jug 24 has a side wall 26 and contains an upper region 27 and a lower region 28 or a lower narrow part 28. The diameter of the lower region 28 is less than the diameter of the upper region 27. The upper region 27 contains an upper hole 29 through which food ingredients to be mixed, for example, ingredients for soup, can be served in the jug 24. The lower region 28 includes a lower hole 30, which is closed by a detachable lower part 14. The lower region 28 has a lower end 31, including the sealing surface 32 of the jug. The spout 33 is located at the end of the side wall 26 in the upper region 27. The cover 34 together with the seal 35 of the cover are designed to close with the possibility of sealing the upper hole 29. The measuring cup 36 can be located in the recess 36a in the cover 34. The handle 37 can be fixed on the side the wall 26 of the jug 24. The jug 24 is preferably made of clear glass so that the user can see the ingredients in the jug 24 during use.

As shown in FIG. 2A, the inner retaining rib 38 may extend circumferentially from the side wall 26 in the lower region 28 to the center of the jug 24. Alternatively, a plurality of inner retaining ribs (not shown) extend around the circumference of the side wall 26 in the lower region 28 to the center of the jug 24. A plurality of external mounting ribs 39, for example, four external mounting ribs 39, may be distributed around the circumference of the jug 24. The external mounting ribs 39 protrude outward from the side wall 26. The external mounting ribs 39 could T secured on the node 25 of the annular projection.

The annular protrusion assembly 25 is located around the lower region 28 and is adapted to receive the lower portion 14. The annular protrusion assembly 25 is fixed to the lower region 28. Preferably, the annular protrusion assembly 25 comprises a first inner annular protrusion 41 and a second outer annular protrusion 40. The inner annular protrusion 41 and the outer annular protrusion 40 are assembled together by a plurality of screws 42. The outer annular protrusion 40 may surround the inner annular protrusion 41, so that the outer annular protrusion 40 and the inner annular protrusion 41 are concentric. The outer mounting ribs 39 may be positioned or secured between the inner annular protrusion 41 and the outer annular protrusion 40, so that the annular protrusion assembly 25 is fixedly mounted in the lower region 28. The outer annular protrusion 40 may extend circumferentially around the lower region 28 and may extend downwardly lower region 28. Similarly, the inner annular protrusion 41 may extend circumferentially around the lower region 28 and may extend downwardly beyond the lower region 28. The outer annular protrusion 40 may extend downwardly beyond the inner a lower annular protrusion 41, so that when the jug assembly 13 is located on a surface such as a table, the jug assembly 13 rests on the outer annular protrusion 40. The inner annular protrusion 41 includes an internal thread 43. The outer annular protrusion 40 and the inner annular protrusion 41 are preferably made of plastic.

As can be seen in FIGS. 2A and 2B, the gasket 44 may be located between the outer annular protrusion 40 and the side wall 26 in the lower region 28. The gasket 44 extends circumferentially around the lower region 28 between the outer annular protrusion 40 and the side wall 26. The gasket 44 is preferably made of rubber. The gasket 44 helps prevent damage to the outer annular protrusion 40 during the life of the blender 10.

A detachable lower portion 14 is shown in FIGS. 3-5. The lower part 14 is designed to close the lower hole 30 of the jug 24. The lower part 14 comprises a blade assembly 16, a blade holder 45, a gripping element 21 for disconnecting the lower part 14 by the user, and a sealing element 46 or a gasket 46 for sealing the lower hole 30 of the jug 24 .

The first upper end 17 of the blade assembly 16 extends into the jug 24 and contains a plurality of blades 18. A plurality of blades 18 are mounted on the shaft 47. The second lower end 19 of the blade assembly 16 is facing the base 11 and includes a connecting assembly 48 including a connecting member 20. Connecting the element 20 is fixed to the shaft 47 by means of a connecting nut 49 or a connecting screw 49. As shown in FIG. 4, a plurality of sealing rings 50, semicircular profile rings 51, washers 52 and supporting elements 53 with screws 54 are also located in the connecting unit e 48 to provide a secure connection between the connecting member 20 and blade assembly 16. The connecting element 20 is preferably round and has, for example, an outer diameter of approximately 29 mm.

The blade holder 45 is arranged to arrange the blade assembly 16 relative to the jug 24. The blade holder 45 is configured to support the shaft 47 substantially parallel to the side wall 26 of the jug 24. The blade holder 45 has a generally circular shape. The blade holder 45 comprises a bottom plate 15 which is adapted to contact the heating plate 22 in the base 11 when the jug assembly 13 is located on the base 11. The lower plate 15 is generally flat. The bottom plate 15 is generally round. The blade holder 45 comprises a central hole 55 through which the shaft 47 passes. The central hole 55 is generally circular. Preferably, the blade holder 45 comprises a peripheral wall 56 protruding upward. The peripheral wall 56 may be substantially vertical. Preferably, the sealing surface 57 of the blade holder extends from the outer edge of the peripheral wall 56. The sealing surface 57 of the blade holder is substantially perpendicular to the peripheral wall 56 and faces upward. The sealing surface 57 of the blade holder extends circumferentially around the wall 56. The blade holder 45 is preferably made of die-cast aluminum to efficiently transfer heat from the heating plate 22 to the food ingredients inside the jug 24. The flat bottom plate 15 is preferably machined with a CNC machine. Optionally, the blade holder 45 is coated with a thermoplastic plastic such as Teflon or any other coating that allows washing the blade holder 45 in a machine.

The gripping element 21 is mounted on the blade holder 45. For example, as shown in FIG. 4, the gripping member 21 and the blade holder 45 are assembled by means of a plurality of screws 58, for example, four screws 58. Optionally, the gripping element 21 has a plurality of protrusions 59, for example, four protrusions 59 aligned with holes (not shown ) on the gripping element 21, which accommodate the screws 58 for assembling the gripping element 21 and the blade holder 45. The protrusions 59 provide easy gripping by the user of the gripping element 21.

Preferably, the gripping element 21 is in the form of a gripping ring 21 having an upper wall 60 and a lower wall 61. The gripping ring 21 forms a protective sleeve around the blade holder 45. Specifically, the gripping ring 21 forms an annular tape or perimeter wall around the flat bottom plate 15. In one embodiment, the bottom wall 61 extends beyond the connecting element 20, so that the bottom plate 15 is protected and prevented from scratching or damage, which will impede heat transfer from the heating plate 22. Consequently, the lower wall 61 of the gripping ring 21 increases the life of the lower part 14 and therefore the life of the blender 10. The upper wall 60 of the gripping ring 21 extends upward around the gasket 46 when disconnecting the lower part 14.

Optionally, the grip ring 21 comprises at least one outer pin-like member 59a or an external finger grip 59a to ensure that the user can grip the grip member 21 securely when the lower portion 11 is detached. Optionally, the grip element 21 includes a plurality of external finger grip 59a formed by protrusions 59 distributed on the bottom wall 61.

The gripping ring 21 is preferably screwed manually into the inner annular protrusion 41. For this purpose, the external thread 62 is formed on the upper wall 60. The external thread is configured to interact with the internal thread 43 of the inner annular protrusion 41 to connect the lower part 11 to the node 25 of the annular protrusion. Preferably, the gripping element 21 is made of plastic. Since both the inner annular protrusion 41 and the gripping ring 21 are preferably made of plastic, both the inner annular protrusion 41 and the gripping ring 21 have elastic properties that ensure reliable installation between the gripping ring 21 and the inner annular protrusion 41. Therefore, an improved connection between the gripping ring 21 and the inner annular protrusion 41 is provided. The simple connection between the gripper ring 21 and the annular protrusion assembly 25 limits the number of parts a user needs to assemble the pitcher assembly 13. This facilitates the use of the blender 10. Since the lower part 14 is easily detachable, the jug 24 and the blades 18 are also more easily cleaned.

Preferably, the gripping ring 21 is made of heat-resistant material, so that the gripping ring 21 can withstand high temperatures and therefore is not damaged when the lower plate 15 is heated. Preferably, the gripping ring 21 is made of heat-insulating material, so that the user does not burn when the lower part is disconnected 14, if the jug assembly 13 has just been removed from the heating plate 22, and the temperature of the bottom plate 15 is still high. Therefore, the gripper ring 21 helps prevent burns to the user and contributes to the safety of the blender 10.

A sealing element 46 or sealing gasket 46 is located between the blade holder 45 and the jug 24. One function of the sealing gasket 46 is to provide a seal between the detachable bottom 14 and the jug 24 to prevent leakage of food ingredients and liquid in the jug 24 to the outside of the jug 24.

Preferably, the seal 46 comprises at least one rubbing rib 63 extending upwardly inside the jug 24. The rubbing rib (s) 63 is designed to create vortex flows among the food ingredients during mixing to increase mixing efficiency. The rubbing rib (s) 63 replaces the ribs made of glass and cast with a jug of 24 known blenders. Preferably, as shown in FIG. 5, at least one rubbing rib 63 extends along the inner surface of the side wall 26 in the lower region 28 of the jug 24. Preferably, at least one rubbing rib 63 comprises a plurality of rubbing ribs 63 distributed around the inner periphery of the IP gasket 46. For example, as shown in FIG. 3, a row of four rubbing ribs 63 is selected. Preferably, the rubbing ribs 63 are spaced equidistant from each other around the inner periphery of IP. For example, if a row of four rubbing ribs 63 is selected, rubbing ribs 63 are distributed every 90 ° around the inner periphery of IP.

Preferably, at least one rubbing rib 63 comprises a support 64 extending in the direction of RD (shown in FIG. 6), which is radial in comparison with the inner periphery IP of the gasket 46. The direction of the RD leads to the center of the inner periphery of the IP. Preferably, the support 64 is located in the upper part U (shown in FIG. 7B) of at least one rubbing rib 63. For example, as shown in FIG. 3 and FIG. 7B, the support 64 is located in the uppermost part of the rubbing rib 63. Optionally, the support 64 has the shape of a truncated pyramid.

Preferably, as shown in FIG. 4, the seal 46 comprises a ring 65 having a first surface S1 facing the blade holder 45 and a second surface S2 facing the jug 24. At least one of the first surface S1 and the second surface S2 comprises concentric compressed ribs CR1, CR2. For example, as shown in FIGS. 3, 4 and 6, the compressed ribs CR1 are located on the first surface S1, and the compressed ribs CR2 are located on the second surface S2. Compressed ribs CR1, CR2 are designed to further improve contact with the lower region 28 of the jug 24.

Preferably, the gasket 46 and at least one rubbing rib 63 form one element made of molded rubber. Alternatively, at least one rubbing rib 63 is glued or fixed as a separate element and is made, for example, of plastic.

Preferably, as shown in FIG. 6, the inner periphery IP comprises a plurality of inner retaining ribs 66 circumferentially distributed around the seal 46. Similarly, the outer periphery OP of the seal 46 may comprise a plurality of outer retaining ribs 67 distributed around the circumference of the annular member 65. The plurality of inner and outer retaining ribs 66, 67 contributes to improved retention of the seal 46 between the peripheral wall 56 of the blade holder 45 and the upper wall 60 behind snap ring 21.

Preferably, the seal 46 is supported by the blade holder 45. Preferably, the seal 46 is held tightly between the upper wall 60 of the gripper ring 21 and the peripheral wall 56 of the blade holder 45. Thus, the gasket 46 does not fall down when the user detaches the lower part 14. When the internal thread 43 is engaged with the external thread 62, the gasket 46 is tightly held in place between the sealing surface 57 of the blade holder and the sealing surface 32 of the pitcher, and furthermore adjoins to the inner retaining rib 38 of the jug 24. This helps to ensure a good seal of the bottom hole 30 of the jug 24.

The exact location and compression of the seal 46 is ensured since the connection between the detachable bottom 14 and the jug assembly 13 is not dependent on the insufficient tolerance of the glass jug 24. Therefore, the blender 10 provides a reliable seal between the detachable bottom and the jug assembly 13. In addition, since the inner annular protrusion 41 and the gripping element 21 are preferably made of plastic, the friction between the inner thread 43 and the outer thread 62 is reduced, and the lower part 14 is easily fixed / detached. In addition, since heat transfer occurs through heat conduction from the heating plate 22 in the base 11 to the lower plate 15 in the jug assembly 13, the jug assembly 13 does not need an electrical connection. This increases safety for the user and ensures that the jug assembly 13 is washed in the machine.

As shown in FIG. 1B and FIG. 1C, the base 11 may include a display screen 68 and a control button 69, allowing the user to select among a variety of cooking programs. The base 11 comprises a heating unit 12 for heating the ingredients in the jug 24, and a gear system 70 configured to couple to the connecting member 20 to rotate the blade assembly 16 in the jug 24. The base 11 further comprises a microcontroller (not shown) for controlling the system 70 gears and heating unit 12.

The heating assembly 12 is shown in more detail in FIGS. 8A-9B. The heating unit 12 includes a heating plate 22 and a heating element 71 extending inside the heating plate 22.

The heating plate 22 has an outer heating surface 72 facing up. The heating plate 22 is generally circular and has a diameter that is smaller than the diameter of the gripping element 21. Preferably, the diameter of the heating plate 22 corresponds essentially to the diameter of the lower plate 15. Preferably, the heating plate 22 is made of die-cast aluminum.

Preferably, the heating plate 22 comprises a central hole 73. The central hole 73 is adapted to receive the connecting member 20 when securing the jug assembly 13 on the base 11. The central hole 73 is preferably circular and has a diameter in the range of [22 mm; 50 mm], for example, a diameter of approximately 36 mm. When assembling the base 11 and the jug assembly 13, the outer heating surface 72 and the lower plate 15 are in contact with each other, providing thermal conductivity from the heating plate 22 to the lower part 14 of the jug 24 and, therefore, to the food ingredients in the jug 24.

Preferably, the heating plate 22 further comprises an additional hole 74. The additional hole 74 preferably has a rounded shape. The additional hole 74 is preferably smaller than the central hole 73. The additional hole 74 has a diameter in the range [6 mm; 30 mm], for example, a diameter of approximately 10 mm. The additional hole 74 passes through the heating plate 22 between the central hole 73 and the circumference of the heating plate 22. Preferably, the additional hole 74 is located in the heating plate 22. Essentially in the middle between the center of the heating plate 22 and the point located on the circumference of the heating plate 22.

The heating element 71 is preferably cast into the heating plate 22. The heating element 71, for example, is made in the form of a copper tube containing a thin spiral-shaped copper wire (not shown) and filled with magnesium oxide surrounding the copper wire. During operation, an electric current passes through the copper wire. Due to the resistance of the copper wire, heat is generated and transferred outward to the heating plate 22 surrounding the copper wire. The heating element 71 has an arcuate shape and extends coaxially with the round heating plate 22. The heating element 71 comprises a first electrical connection C1 in the form of a first end or a first cold pin and a second electrical connection C2 in the form of a second end or a second cold pin. The first and second electrical connections C1, C2 extend substantially vertically downward under the heating plate 22. An additional hole 74 is located in the heating plate 22 between the first and second electrical connections C1, C2.

The temperature sensor 23 or the temperature sensor is preferably in the form of a thermistor 23. The thermistor 23 is located in the base 11. The thermistor 23 passes through an additional hole 74. Therefore, the thermistor 23 is located between the first electrical connection and the second electrical connection C1, C2. Preferably, the thermistor 23 extends vertically at the base 11. Preferably, the thermistor 23 moves in the additional hole 74. Preferably, the thermistor 23 slides vertically through the additional hole 74. Preferably, the thermistor 23 moves in the vertical direction D relative to the heating plate 22. Preferably, the thermistor 23 has negative temperature coefficient (NTC).

Preferably, the cap 75 is located on the upper end 78 of the thermistor 23. The cap 75 seals the upper end 78 of the thermistor 23. The cap 75 is mounted on the thermistor 23. The cap 75 comprises a flat top 76. The upper end 78 of the thermistor 23 is in contact with the flat top 76. Preferably, the cap 75 has a cylindrical shape. Preferably, cap 75 has a diameter in the range [5 mm; 20 mm]. The cap is preferably made of heat-resistant material. Therefore, the cap 75 withstands high temperatures and is not damaged during operation of the heating unit 12. The cap 75 is preferably made of a material with high thermal conductivity to ensure that heat from the heated lower plate 15 is effectively transferred to the thermistor 23. The cap 75 is preferably made of a material with low electrical conductivity . For example, cap 75 is made of ceramic material.

Advantageously, the heating plate 22 and the cap 75 are dimensioned, as a result of which an air gap 79 is formed between the heating plate 22 and the cap 75. For the formation of the air gap 79, the guide element 80 is preferably located in an additional hole 74 for holding the thermistor 23 with the cap at a distance from the heating plate 22. The guide element 80 is preferably mounted on the heating plate 22 and accommodates the thermistor 23 with a cap in the additional hole 74. The air gap 79 is made in the form of a generally annular hollow volume passing between the heating plate 22 and the thermistor 23 with a cap. Preferably, the air gap 79 has a width of at least 1 mm. The air gap 79 ensures that the thermal conductivity from the heating element 71 directly to the thermistor 23 is limited. Essentially, the air gap 79 acts as a heat insulator between the heating element 71 and the thermistor 23. Therefore, the air gap 79 ensures that the heat coming from the bottom plate 15 to the thermistor 23 prevails over the heat coming from the heating element 71, and therefore , the thermistor 23 reacts to the heat coming from the bottom plate 15, and not the heat coming from the heating element 71. This ensures that the temperature is determined correctly by the thermistor 23 in the jug 24 without violation, due to ovlennogo heat coming from the heating element 71.

Optionally, the insulating element 81 is located in the air gap 79 to further limit the heat conductivity from the heating element 71 directly to the thermistor 23. As shown in Fig. 8A, the insulating element 81, for example, is made in the form of an insulating tube 81 located around the circumference of the additional hole 74. The insulating tube 81 is located at a distance from the thermistor 23 with a cap. An insulating tube 81 surrounds the thermistor 23 with a cap.

The thermistor 23 with the cap is arranged to move between the first position P1 and the second position P2. In the first position P1 shown in FIG. 8A and FIG. 8B, the upper portion 76 projects from the outer heating surface 72. In other words, when the cap 75 is moved to the first position P1, the upper part 76 protrudes a predetermined distance from the outer heating surface 72. This distance is preferably in the range [1 mm; 10 mm], for example, 2 mm. The cap 75 is configured to occupy the first position P1 when the lower part 14 is not in contact with the heating plate 22. In the second position P2 shown in FIG. 7B, the upper part 76 is aligned or flush with the outer heating surface 72. The cap 75 is movable to the second position P2 when the lower part is in contact with the heating plate 22. The spring mechanism 77 may be located in the base 11 for applying a vertical holding force to the thermistor 23, so that the thermistor 23 is shifted up to the first position P1. The thermistor 23 with the cap is located in the heating unit 12, so that when the jug assembly 13 is placed on the base 11, the lower plate 15 touches and presses the thermistor 23 with the cap, forcing the thermistor 23 with the cap from the first position P1 to the second position P2.

The guide member 80 guides the cap 75 vertically when the cap moves through the additional hole 74 between the first position P1 and the second position P2. Optionally, a stop 82 is located at the lower end 83 of the cap 75 to prevent the cap 75 from moving a distance greater than a predetermined distance.

Preferably, the sealed thermistor 23 touches the bottom plate 15, while the jug assembly 13 is in place on the base 11, so that the thermistor 23 can measure the temperature of the bottom plate 15 and therefore provide the user with temperature feedback from the food ingredients in the jug 24. The position of the thermistor 23 in the heating unit 12 is such that an accurate determination of the temperature of the lower part 14 is provided. Therefore, the blender 10 provides an efficient preparation of food ingredients and helps prevent undercooking, digestion, transfusion or evaporation to dryness.

Although in the above embodiments, the blender 10 has been described as a cooking blender, the present utility model can be applied to any other kitchen device having a heating plate 22 and a central drive system, such as a food processor or a mixing and grinding device.

The above embodiments, as described, are illustrative only and are not intended to limit the technical methods of the present utility model. Although the present utility model is described in detail with reference to preferred embodiments, those skilled in the art should understand that the technical methods of the present utility model can be modified or equally replaced without departing from the protective domain of the utility model formula of the present utility model. In particular, although the utility model has been described on the basis of a kitchen device, it can be applied to an industrial blender or to mix food ingredients or inedible materials. In the utility model formula, the term “comprising” does not exclude other elements or steps, and the indefinite article ʺaʺ or ʺanʺ does not exclude a plurality. Any reference numerals in a utility model formula should not be construed as limiting the scope of the utility model formula.

Claims (19)

1. A blender (10) for mixing ingredients, containing: - the base (11) containing the heating unit (12), - a container (13) for containing ingredients, and the container (13) contains a lower part (14), detachable manually, and the lower part (14) contains: - the bottom plate (15) for contact with the heating unit (12), - the node (16) of the blade passing through the lower plate (15), and the node (16) of the blade has a first end (17) extending into the container (13) and containing at least one blade (18), and a second end (19 ) facing the base (11) and containing a connecting element (20) for receiving a rotational force from the base (11), - a gripping element (21) surrounding the lower plate (15) for manually gripping and detaching the lower part (14), the gripping element (21) extending down at least partially along the connecting element (20) and made of heat-insulating material. 2. The blender according to claim 1, in which the gripping element (21) extends beyond the connecting element (20). 3. The blender according to claim 1 or 2, in which the gripping element (21) forms a generally annular ribbon. 4. The blender according to any preceding paragraph, in which the gripping element (21) is made of heat-resistant material. 5. The blender according to any preceding paragraph, in which the gripping element (21) is made of plastic. 6. The blender according to any preceding claim, wherein the gripping element (21) comprises at least one rod-shaped element (59a). 7. The blender according to any preceding paragraph, in which the gripping element (21) contains at least one protrusion (59). 8. The blender according to any preceding claim, wherein the container (13) comprises a lower region (28) and a first annular protrusion (41) extending around the lower region (28), the first annular protrusion (41) extending downward, the first annular protrusion (41) comprises an internal thread (43) configured to interact with an external thread (62) formed on the lower part (14) to disconnect the lower part (14) from the container (13). 9. The blender of claim 8, in which the external thread (62) is formed on the wall (60) of the gripping element (21). 10. The blender according to claim 8 or 9, in which the first annular protrusion (41) is made of plastic. 11. A blender according to any one of claims 8 to 10, in which the container (13) comprises a second annular protrusion (40) surrounding the first annular protrusion (41), and between the second annular protrusion (40) and the side wall (26) of the container ( 13) the gasket (44) is located. 12. The blender according to any preceding paragraph, in which the lower part (14) comprises a sealing element (46) located between the lower plate (15) and the container (13). 13. The blender according to claim 12, in which the gripping element (21) extends upward around the sealing element (46), so that the sealing element (46) is held in the gripping element (21) by disconnecting the lower part (14) from the container (13) . 14. The blender according to claim 12, depending on claim 8, in which, when the internal thread (43) engages with the external thread (62), the sealing element (46) is tightly held in place between the lower plate (15) and the container (13).

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