RU2832470C2 - Blender with bidirectional rotating knives - Google Patents

Abstract

FIELD: household appliances.

SUBSTANCE: invention relates to a blender with bidirectional rotating blades, with possibility of rotation of a pair of blades in opposite directions with different rotation speeds. Blender with bidirectional rotating blades comprises a blade assembly including a main blade shaft, which is configured to rotate the first blade as a whole and the first main connector in the forward direction, and the reverse rotation blade shaft, which is configured to ensure the second blade rotation and a first connector of reverse rotation and has a structure which is coaxial to the main blade shaft and through which the main blade shaft passes; and a reduction gear assembly including a main gear shaft, which is configured to enable rotation of a second main connector, which is engaged with the first main connector, and the main gear in the forward direction, at least one auxiliary gear which is engaged with the main gear and rotates in the reverse direction, a ring gear for which the auxiliary gear is internal and engaged therewith, and a second reverse rotation connector which is configured to rotate integrally with the ring gear in the reverse direction and transmit the reverse rotation to the first reverse rotation connector, wherein in the inner area of one of the first main connector and the second main connector, the other of the first main connector and the second main connector is inserted for engagement therewith; first reverse rotation connector is made integral with the lower end portion of the reverse rotation blade shaft; one of the first reverse rotation connector and the second reverse rotation connector is inserted into the inner area of the other of the first reverse rotation connector and the second reverse rotation connector and is engaged therewith, in the casing, having a reduction gear assembly, there is a mounting section of the container, which is formed along the periphery of the upper end of the casing and on which a food container is located, a wall body of a recessed portion, which extends downward from the inner side end portion of the container mounting portion, and a casing top plate which extends inward from the recessed portion wall body lower end and is formed at a position below the container mounting portion; in the recessed portion, which is the inner area surrounded by the recessed portion wall body and the upper casing plate, the first main connector and the second main connector are connected to each other, and the first reverse rotation connector and the second reverse rotation connector are connected to each other; second main connector is connected to the upper end of the main gear shaft using the fastener, and after separation of the fastener from the second main connector and the main gear shaft in a position in which the container is separated upward from the casing, second main connector is separated from the main gear shaft to the upper side of the casing upper plate; knife assembly is installed to pass through the lower portion of the container for accommodating food products and is detachably connected to the container; and at separation of the casing having the reducer assembly installed therein, the reducer assembly is separated from the blade assembly.

EFFECT: easier disassembly and assembly of elements, ensuring safe use of the blender and increasing durability of its elements.

21 cl, 10 dwg

Description

Field of technology to which the invention relates

The present invention relates to a blender with bidirectionally rotating blades, and more particularly to a blender with bidirectionally rotating blades, which is designed to provide rotation of a pair of blades in opposite directions at different rotation speeds.

Prerequisites for the creation of an invention

Generally, a blender is an electrically powered device that processes food products such as fruits, vegetables, and grains by chopping, juicing, mixing, cutting, or grinding the food products to enable their consumption in various forms.

The blender includes an electric motor, blades that receive rotational force from the motor to rotate, and a container in which the blades are located. In this case, since the load on the motor increases when the blades rotate in only one direction, the known blender with bidirectional rotating blades has one electric motor that rotates two blades in opposite directions.

As a prior art relating to a blender having bidirectionally rotating blades, Korean Utility Model Registration No. 200196399 (Invention Title: "Chopper-Mixer") was disclosed.

The mixer of the prior art includes a pair of knives that rotate in opposite directions and a gear part designed to transmit the power of an electric motor for simultaneous rotation of the pair of knives. In this case, to transmit the reverse rotation to one of the pair of knives, the rotational force is successively transmitted to a spur gear, a radial gear, a reduction gear and a spur gear.

In a blender, it is necessary to set the rotation speeds of a pair of knives so that they differ from each other depending on the food being ground. In order to set the rotation speeds of a pair of knives so that they differ from each other, the gear ratios must be set differently. However, since the gears shown in the relevant prior art are external to the adjacent gears and thus the variable range of the gear ratio is inevitably limited, the rotation speeds of a pair of knives can only be set to differ from each other in a limited range.

In addition, since it is not easy to separate the knives from the container, and the knives remain connected to the gear part when the user wants to wash the container, the user must hold the entire container connected to the gear part to wash the container, and thus there is a problem that the user must hold a heavy object. In addition, since it is difficult to separate the knives from the container, there is a problem that when the user washes the container without removing the knives, he may be injured.

The essence of the invention

Technical problem

The present invention relates to the creation of a blender having bidirectionally rotating blades, which facilitates disassembly and assembly of elements, ensures safe use of the blender by the user and increases the durability of the elements.

Technical solution

One aspect of the present invention describes a blender with bidirectionally rotating blades, comprising a blade assembly including a main blade shaft, which is configured to provide integral rotation of a first blade and a first main connector in a forward direction, and a reverse rotation blade shaft, which is configured to provide integral rotation of a second blade and a first reverse rotation connector, and has a structure that is coaxial with the main blade shaft and through which the main blade shaft passes, and a gear unit including a main gear shaft, which is configured to provide forward rotation of a second main connector, which is engaged with the first main connector and the main gear, at least one auxiliary gear, which is engaged with the main gear and rotates in the reverse direction, a ring gear relative to which the auxiliary gear is internal and with which it is engaged, and a second reverse rotation connector, which is configured to rotate integrally with the ring gear in the reverse direction and transmit the reverse rotation to the first reverse rotation connector. Advantages of the invention

According to the present invention, since the pair of blades can be provided with different rotation speeds in a wide range, the blender can meet various purposes in grinding food, and thus the marketing potential of the blender can be increased.

In addition, since the blade unit can be easily separated from the container, injury to the user when washing the container can be prevented.

In addition, since the knife unit and the gear unit are separated at the same time when the container is separated from the casing, the container is lightweight, and thus the inconvenience to the user due to the weight of the container can be prevented.

In addition, since the shaft and a plurality of gears that transmit the rotation of the electric motor are located inside the gear housing, and the gear housing is located inside the casing, the elements that generate operating noise are twice surrounded by the gear housing and the casing, and thus the operating noise can be minimized.

In addition, since the connectors that transmit forward and reverse rotation between the knife assembly and the gear unit are located in a recessed portion that is an area between the container and the casing, and the knife assembly and the gear unit are simultaneously separated when the container is separated from the casing, at least some of the connectors are connected so as to be easily separated, and when the connectors fail and require repair, the connectors can be easily replaced, and thus the repair work can be facilitated.

In addition, since a portion of the upper plate of the casing in which a through hole is formed into which the second reverse rotation connector is inserted protrudes further upward than the outer side edge of the upper plate of the casing, the flow of moisture into the reducer unit can be blocked, and thus the durability of the elements located in the reducer unit can be increased.

Brief description of the drawings

Fig. 1 is a sectional view of the internal structure of a blender in accordance with the present invention;

Fig. 2 is a sectional view with spatial separation of the elements of the blender shown in Fig. 1;

Fig. 3 is a perspective view with spatial separation of the elements of the blender shown in Fig. 1;

Fig. 4 is a perspective view with spatial separation of the structural elements of the knife assembly shown in Fig. 1;

Fig. 5 is a perspective view with spatial separation of the structural elements of the gear unit shown in Fig. 1;

Fig. 6 is a perspective view of the main knife shaft, the reverse rotation knife shaft, the second main connector and the element of the second reverse rotation connector, which are shown in Fig. 1;

Fig. 7 is a sectional view of the design of the knife assembly shown in Fig. 1;

Fig. 8 is a sectional view of the connecting structure of the connectors shown in Fig. 1;

Fig. 9 - sectional view of the design of the gear unit shown in Fig. 1;

Fig. 10 - bottom view of the gearbox unit, from which the gearbox housing cover has been removed.

Embodiments of the invention

Below, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 1 and 2, a blender 1 having bidirectionally rotating blades according to the present invention includes a container 10, a blade unit 100, a gear unit 200, an electric motor 300 and a casing 20.

The container 10 contains food products and includes a container body 11 having a reverse trapezoidal cross-section, a through hole 14 formed in the central section of the lower section 12 of the container body 11, a flange 15 of the through hole projecting downwards from the lower section 12 along the periphery of the edge of the through hole 14, and a lower flange 13 of the container having a diameter greater than the diameter of the flange 15 of the through hole, projects downwards from the lower section 12 and has a structure that is coaxial with the flange 15 of the through hole.

The knife assembly 100 includes a set of knives 100a, a sealing element 150 configured to maintain air tightness between the set of knives 100a and the lower section 12 of the container 10, and a fastening nut 160 configured to secure the set of knives 100a to the lower section 12 of the container 10.

The specific structure of the knife assembly 100 will be described with reference to Figs. 4, 6 and 7.

The knife set 100a includes a main knife shaft 111 having a length in the vertical direction, a first knife 110 connected to an upper portion of the main knife shaft 111, a first main connector 11Id formed on a lower portion of the main knife shaft 111, and a first cover 112 connected to an upper end of the main knife shaft 111 for fixing the first knife 110.

The main knife shaft 111, on which the first main connector 11Id is formed, the first knife 110 and the first cover 112 rotate in the forward direction due to the actuation of the electric motor 300.

The first knife 110 includes a connecting section 110a of the shaft, on which a through hole 110c of the shaft is formed, into which the connecting section 111a of the first knife of the main knife shaft 111 is inserted, and a knife section 110b, which extends to both sides from both ends of the connecting section 110a of the shaft. The knife section 110b may have a shape that is bent at least in one place in the longitudinal direction.

The main knife shaft 111 includes a connecting section 111a of the first knife, connected to the first knife 110 and the first cover 112, a cylindrical shaft housing 111b, which has a diameter larger than the diameter of the connecting section 111a of the first knife, a projecting step 111c, which projects outward with a constant vertical width from the central lower section of the shaft housing 111b along the periphery of its outer side surface, and a first main connector 111d, formed to pass from the lower end section of the shaft housing 111b.

The connecting section 111a of the first knife includes a screw threaded section 111-1a on which threads are formed along the periphery of its outer side surface, and a cut surface 111-2a formed by forming a D-shaped cut, so that the section of the outer side surface is a vertical surface. The screw threaded section 111-1a and the cut surface 111-2a can be formed as a pair of screw threaded sections 111-1a and a pair of cut surfaces 111-2a in positions opposite to each other, and can be alternately located along the periphery of the outer side surface of the connecting section 111a of the first knife.

Since the vertical surface, which has a shape corresponding to the cutting surface 111-2a, is formed on the through hole 110c of the shaft of the first knife 110, then when the connecting section 111a of the first knife is inserted into the through hole 110c of the shaft of the first knife 110, the first knife 110 rotates as a single unit with the main knife shaft 111.

Since the shaft housing 111b is formed with a diameter larger than the diameter of the connecting portion 111a of the first knife, a step is formed at the boundary portion between the connecting portion 111a of the first knife and the shaft housing 111b, and when the connecting portion 111a of the first knife is inserted into the through hole 110c of the shaft of the first knife 110, due to the step, the lower surface of the first knife 110 is located on the upper end surface of the shaft housing 111b.

Since screw threads are formed on the inner side surface of the groove into which the connecting portion 111a of the first knife in the first cover 112 is inserted, and the screw threads of the first cover 112 are screw-connected with the screw threaded portion 111-1a of the connecting portion 111a of the first knife, the first knife 110 is firmly connected to the main knife shaft 111 by the first cover 112.

Since the first main connector 111d is formed integrally with the main knife shaft 111 and has the shape of a hexagonal rod having a hexagonal cross-section, the first main connector 111d is connected to the second main connector 210 and transmits forward rotation to the first knife 110.

When the first main connector 111d, instead of being formed integrally with the main blade shaft 111, is formed as a separate connector and then connected to the main blade shaft 111 using a fastener, the number of elements increases, the assembly structure becomes complicated, and the manufacturing cost increases. In addition, when the first main connector and the main blade shaft are connected to each other using a fastener, due to the connection of the two elements, an axial displacement of the main blade shaft may occur. In the present invention, the first main connector 11Id is formed integrally with the main blade shaft 111, so that the number of elements is reduced, the assembly structure is simplified, the manufacturing cost is reduced, and the axial displacement of the main blade shaft 111 is prevented.

In addition, the set of knives 100a includes a reverse rotation knife shaft 125, which has a structure that is coaxial with the main knife shaft 111 and through which the main knife shaft 111 passes, a first reverse rotation connector 125g formed in one piece with a lower section of the inner side of the reverse rotation knife shaft 125, a second knife 120 connected to an upper section of the reverse rotation knife shaft 125, and a second cover 121 connected to the reverse rotation knife shaft 125 on the upper section of the second knife 120, so that the second knife 120 is fixed on the reverse rotation knife shaft 125.

The reverse rotation knife shaft 125, which is formed integrally with the first reverse rotation connector 125g, the second knife 120 and the second cover 121 rotate in the reverse direction due to the forward rotation of the electric motor 300, converted into reverse rotation.

The second knife 120 includes a connecting section 120a of the shaft, in which a through hole 120c of the shaft is formed, and a knife section 120b, which extends to both sides from both ends of the connecting section 120a of the shaft. The knife section 120b may have a shape that is curved at least in one place in the longitudinal direction. A pair of connecting surfaces 120d of the knife, each of which is a vertical surface formed by making a D-shaped cut, are formed in positions opposite to each other, on the inner side surface of the connecting section 120a of the shaft surrounding the through hole 120c of the shaft.

The reverse rotation knife shaft 125 has a cylindrical shape having a length in the vertical direction, and has a structure in which a plurality of steps are formed on the outer side surface from top to bottom.

The reverse rotation knife shaft 125 includes a cylindrical section 125a of the shaft housing having a hollow inner section, a connecting section 125b of the second knife which is formed on the upper section of the section 125a of the shaft housing and is connected to the second knife 120 and the second cover 121, a protruding support section 12 5 c which is formed between the upper end of the section 125a of the shaft housing and the connecting section 125b of the second knife and has a diameter greater than the diameters of the connecting section 125b of the second knife and the section 125a of the shaft housing, a section 125d of the upper shaft housing which is formed on the lower section of the protruding support section 125c and has a diameter which is greater than the diameter of the section 125a of the shaft housing and less than the diameter of the protruding support section 125c, a first annular groove 125e for insertion formed by a concave circumferential outer side surface of the lower end of the section 125a of the shaft housing and into which the first retaining ring 171 is inserted, a second annular groove 125f formed by a concave circumferential inner side surface of the section 125a of the shaft housing and into which the second retaining ring 172 is inserted, and a first reverse rotation connector 125g formed on the lower end section of the inner side surface of the section 125a of the shaft housing.

The upper portion of the reverse rotation knife shaft 125 is closed, but a through hole 125h through which the main knife shaft 111 passes is formed in the central portion of the upper portion of the reverse rotation knife shaft 125.

A pair of cutting surfaces 125-1b, each of which is formed by making a D-shaped cut, and a screw threaded portion 125-2b on which screw threads are formed, are formed at positions opposite to each other on the periphery of the outer side surface of the connecting portion 125b of the second knife. When the connecting portion 125b of the second knife is inserted into the through hole 120c of the shaft of the second knife 120, the pair of cutting surfaces 125-1b and the pair of connecting surfaces 120d of the knife, which are formed in the through hole 120c of the shaft, face each other to engage with each other during rotation. Thus, the reverse rotation knife shaft 125 and the second knife 120 rotate as a single unit.

The first reverse rotation connector 125g is formed on the inner side surface of the shaft housing section 125a, has gear teeth formed along the periphery of its inner side surface, and is connected to the second reverse rotation connector 224 for transmitting reverse rotation thereto.

The first main connector 111d is located in the inner region of the first reverse rotation connector 125g, so that the inner side surface of the first reverse rotation connector 125g and the outer side surface of the first main connector 111d are located at a distance from each other. Thus, each of the forward rotation and the reverse rotation is transmitted.

The second cover 121 includes a cover body 121a configured to close the side surface of the connecting portion 125b of the second knife of the reverse rotation knife shaft 125, a cover upper surface portion 12lb formed on the upper portion of the cover body 121a to close the upper surface of the connecting portion 125b of the second knife, screw threads 121c formed on the inner side surface of the cover body 121a, and a through hole 121d formed to pass through the central portion of the portion 121b of the cover upper surface. The screw threads 121c are screw-connected to the screw threaded portion 125-2b of the connecting portion 125b of the second knife, and thus the second cover 121 rotates integrally with the reverse rotation knife shaft 125.

The first bearing 143 and the second bearing 144, arranged vertically at a distance from each other, are arranged between the outer side surface of the main knife shaft 111 and the inner side surface of the reverse rotation knife shaft 125, so that the main knife shaft 111 and the reverse rotation knife shaft 125 can rotate relative to each other. Due to the fact that the first bearing 143 and the second bearing 144 are arranged in this way, the main knife shaft 111 can be prevented from moving in the axial direction. Here, although it has been described above that two bearings 143 and 144 are arranged in the present embodiment, more than two bearings can also be arranged.

The first oil seal 142 can be arranged on the upper portion of the first bearing 143 to maintain air tightness between the inner side surface of the reverse rotation knife shaft 125 and the outer side surface of the main knife shaft 111. Due to the presence of the first oil seal 142, the food product in the container 10 or moisture can be prevented from passing into the first bearing 143 through the gap formed between the outer side surface of the main knife shaft 111 and the inner side surface of the connecting portion 125b of the second knife forming the through hole 125h of the reverse rotation knife shaft 125.

The first bearing 143 may be any of a bearing that requires oil and a bearing without lubrication that does not require oil. When the first bearing 143 is designed as a bearing without lubrication, there is no possibility of oil passing into the container 10. When the first bearing 143 is designed as a bearing that requires oil, the first oil seal 142 prevents the oil of the first bearing 143 from passing into the container 10.

The lower surface of the inner ring of the first bearing 143 is supported by the upper surface of the protruding step 111 c, the upper surface of the inner ring of the second bearing 144 is supported by the lower surface of the protruding step 111 c, and the lower surface of the outer ring of the second bearing 144 is supported by the second retaining ring 172.

Thanks to the above-mentioned structure, when the main knife shaft 111 is inserted into the reverse rotation knife shaft 125 in a position in which the first oil seal 142 and the first bearing 143 are inserted in a position above the protruding step 111 c inside the reverse rotation knife shaft 125, since the protruding step 111 c is engaged with the first bearing 143 and the insertion depth of the main knife shaft 111 is limited, the assembly work is facilitated. In addition, when the second bearing 144 is inserted onto the lower portion of the protruding step 111 c, the insertion position of the main knife shaft 111 is determined by the protruding step 111 c. Therefore, even when a separate member is not provided, the main knife shaft 111, the first bearing 143 and the second bearing 144 can be easily assembled into the reverse rotation knife shaft 125.

The set of knives 100a further includes a holder 130 configured to ensure that the set of knives 100a is positioned on the lower portion 12 of the container 10 in a position in which the set of knives 100a can pass through the through opening 14 of the container 10.

The holder 30 includes a holder section 131, which has a substantially cylindrical shape and has an upper section, on which a through hole 131a is made to ensure that the main knife shaft 111 and the reverse rotation knife shaft 125 pass through it, an annular edge section 132, which extends outwardly along the periphery of the lower side edge of the holder section 131, a cylindrical support section 133, which projects downwardly from the lower surface of the holder section 131, and a third annular groove 134 for insertion, which is formed by concave along the periphery of the inner side surface of the support section 133 and into which the third retaining ring 173 is inserted.

Since the holder portion 131 is formed with a structure that projects higher than the edge portion 132, a region in the vertical direction can be provided for allowing the second oil seal 145 and the third bearing 146 to be inserted onto the holder portion 131 and the support portion 133.

When the support portion 133 of the holder 130 is inserted into the through hole 14 of the container 10, and the edge portion 132 of the holder 130 is engaged with the lower portion 12 around the through hole 14 of the container 10, the set of knives 100a is located on the lower portion 12 of the container 10.

The third bearing 146 is located between the inner side surfaces of the holder section 131 and the support section 133 and the outer side surface of the reverse rotation knife shaft 125 to ensure reverse rotation of the reverse rotation knife shaft 125.

The second oil seal 145 is located on the upper portion of the third bearing 146 to maintain air tightness between the inner side surface of the holder portion 131 and the outer side surface of the reverse rotation knife shaft 125.

By having the second oil seal 145, the food product in the container 10 or moisture can be prevented from passing into the third bearing 146 through the gap formed between the inner side surface of the holder portion 131, which surrounds the through hole 131a, and the outer side surface of the protruding support portion 125c. In addition, the third bearing 146 can be any of a bearing that requires oil and a non-lubricated bearing that does not require oil. When the third bearing 146 is configured as a non-lubricated bearing, there is no possibility of oil passing into the container 10. When the third bearing 146 is configured as a bearing that requires oil, the second oil seal 145 prevents the oil of the third bearing 146 from passing into the container 10.

The annular sleeve 174 of the ring is inserted on the periphery of the outer side surface of the lower end section of the reverse rotation knife shaft 125, and the lower surface of the sleeve 174 of the ring is supported by the first retaining ring 171.

The lower surface of the inner ring of the third bearing 146 is supported by the upper surface of the ring bushing 174, and the lower surface of the outer ring of the third bearing 146 is supported by the third retaining ring 173.

The sealing element 150 is located between the lower surface of the edge section 132 of the holder 130 and the upper surface of the lower section 12 of the container 10 to maintain air tightness between them.

The fastening nut 160 is designed with the possibility of connecting in the position in which the holder 130 of the set of knives 100a is inserted into the through hole 14 formed on the lower section 12 of the container 10, with the section of the holder 130 that projects toward the lower section of the through hole 14, and fixing the set of knives 100a on the lower section 12 of the container 10.

The fastening nut 160 includes a section 160a of the nut body made in the form of a ring, a through hole 160b made to pass through the central section of the section 160a of the nut body, and an outer flange 160c that extends upward along the periphery of the outer side edge of the section 160a of the nut body.

The support portion 133 of the holder 130 is inserted into the through hole 160b of the fastening nut 160. In this case, screw threads are formed on the outer peripheral surface of the lower portion of the support portion 133, screw threads are also formed on the inner peripheral surface 160d of the portion 160a of the nut body, which forms the through hole 160b, and due to the connection of the screw threads, the fastening nut 160 and the holder 130 are firmly connected to each other.

When the support portion 133 of the holder 130, which is connected to the set of knives 100a, is inserted into the through hole 14, the lower portion of the support portion 133 projects into the lower portion of the through hole 14. In this case, the sealing member 150, connected to the lower portion of the edge portion 132 of the holder 130, reaches the position of being located on the upper portion of the flange 15 with the through hole.

In this position, when the fastening nut 160 is connected by a screw connection to the support section 133 protruding toward the lower section of the through hole 14, the upper surface of the outer flange 160 with the fastening nut 160 presses the lower surface of the lower section 12 of the container 10 upward.

Therefore, the sealing member 150, which is located between the lower surface of the edge portion 132 of the holder 130 and the upper surface of the flange 15 of the through hole, is pressed downward, and thus air tightness is maintained between the lower surface of the edge portion 132 and the upper surface of the sealing member 150 and between the lower surface of the sealing member 150 and the upper surface of the flange 15 of the through hole.

When the blade unit 100 is connected to the container 10 by the fastening nut 160 as described above, since the blade unit 100 can be easily separated from the container 10, it becomes easy to wash the container 10. In addition, since the user can only wash the container 10 after dismantling the blade unit 100 therefrom, the weight of the container 10 becomes light, and thus the inconvenience caused by the weight of the container 10 can be prevented when washing the container 10.

As shown in Fig. 1-3, the casing 20, in which the electric motor 300, configured to generate forward rotation, and the gear unit 200, configured to simultaneously transmit forward rotation of the electric motor 300 and convert the forward rotation into reverse rotation, and then also transmit the reverse rotation, are located, is located on the lower portion of the container 10.

The casing 20 includes a casing body 21, in which a conical section is formed along the outer periphery of the upper section, and a section below the conical section is formed in a cylindrical shape, a container mounting section 24, which extends inward in a horizontal direction from the upper end of the casing body 21 along its periphery, a recessed section wall body 26, which extends downward from the inner end section of the container mounting section 24, so that a recessed section 25 is formed in its inner region, an upper casing plate 22, which extends inward from the lower end of the recessed section wall body 26 along its periphery and which has a through hole 22a formed in the central section, and a casing cover 27, configured to close the open lower section of the casing body 21.

The upper plate 22 of the casing is located in a position below the mounting portion 24 of the container, which is the edge portion of the casing 20, so that the recessed portion 25 is formed. When the container 10 is mounted on the upper portion of the casing 20, the edge of the lower portion 12 of the container 10 is located on the mounting portion 24 of the container, and the lower flange 13 of the container 10 is inserted along the edge of the recessed portion 25. In this case, the lower flange 13 of the container is directed by the inner side surface of the body of the wall 26 of the recessed portion. In addition, after the container 10 and the casing 20 are connected to each other, the lower flange 13 of the container is supported by the body of the wall 26 of the recessed portion, and thus, the movement of the container 10 can be prevented.

The second main connector 210 and the second reverse rotation connector 224 are configured to pass through the through hole 22a. In addition, in the recessed portion 25, which is the region between the lower portion 12 of the container 10 and the upper plate 22 of the casing, the first main connector 111d and the second main connector 210 are connected to each other, and the first reverse rotation connector 125g and the second reverse rotation connector 224 are connected to each other.

Since the upper portion of the reduction gear unit 200 is covered by the upper casing plate 22, the flow of moisture or foreign substances into the reduction gear unit 200 can be prevented. In addition, since the inner side of the upper casing plate 22, in which the through hole 22a is formed, protrudes upward to be higher than the edge of the outer side of the upper casing plate 22, even when moisture passes into the recessed portion 25, the flow of moisture into the reduction gear unit 200 through the through hole 22a is prevented.

In addition, since in the recessed portion 25, which is the region between the container 10 and the casing 20, the first main connector 11Id and the second main connector 210 are connected to each other, and the first reverse rotation connector 125g and the second reverse rotation connector 224 are connected to each other, then when the container 10 is separated from the upper side of the casing 20, the connectors are disconnected. Therefore, since when the user lifts the container 10 to wash the container 10, the container 10 is separated from the casing 20, and the reducer unit 200 is separated from the blade unit 100, the weight of the container 10 becomes light, and thus the convenience of the user can be improved.

In addition, since in the recessed portion 25 the second main connector 210 is connected to the main gear shaft 212 by a fastening member, when the container 10 is separated upward from the casing 20, the fastening member is visible. Therefore, when the fastening member is separated from the second main connector 210 and the main gear shaft 212, the second main connector 210 reaches the position of separation from the main gear shaft 212, and thus the second main connector 210 can be easily separated from the reduction unit 200. Therefore, when damage occurs to the second main connector 210 and the elements connected to it and repair is necessary, since the second main connector 210 can be easily replaced, the repair work is facilitated.

The specific construction of the gear unit 200 will be described with reference to Figs. 5, 6, 8 and 9.

The gear unit 200 includes a second main connector 210 connected to the first main connector 11Id, a main gear shaft 212 having an upper end connected to the second main connector 210 and a lower end connected to the shaft 310 (see Fig. 1) of the electric motor 300 for forward rotation, a plurality of gears 213, 230-1, 230-2, 230-3 and 240, including a ring gear 24 0, configured to convert the forward rotation of the main gear shaft 212 into reverse rotation, a second reverse rotation connector element 220 having a second reverse rotation connector 224 formed thereon for transmitting the reverse rotation through the plurality of gears 213, 230-1, 230-2, 230-3 and 240, to the first reverse rotation connector 125g, a housing 250 gear reducer, designed with the possibility of surrounding the upper section and the side surface of the gear reducer unit 200, which are sections of the outer side of the gear reducer unit 200, and a cover 260 of the gear reducer housing, designed with the possibility of closing the open lower section of the gear reducer housing 250.

Since the main gear shaft 212 and the plurality of gears 213, 230-1, 230-2, 230-3 and 240, which generate operating noise in the process of transmitting the rotational force of the electric motor 300, are located inside the reduction gear housing 250, and the reduction gear housing 250 is located inside the casing 20, the main gear shaft 212 and the plurality of gears 213, 230-1, 230-2, 230-3 and 240, which generate operating noise, are twice surrounded by the reduction gear housing 250 and the casing 20, and thus the generation of operating noise can be minimized when driving the electric motor 300.

As shown in Fig. 3, the gear unit 200 can be divided into a second main connector 210 and an auxiliary gear unit 200a. The auxiliary gear unit 200a can be configured to include a main gear shaft 212, a reverse rotation connector element 220, a plurality of gears 213, 230-1, 230-2, 230-3 and 240, a gear housing 250 and a gear housing cover 260.

The plurality of gears 213, 230-1, 230-2, 230-3 and 240 includes the main gear 213, the first auxiliary gear 230-1, the second auxiliary gear 230-2, the third auxiliary gear 230-3 and the ring gear 240.

The second main connector 210 has a cylindrical shape having an inner region formed therein and includes a connecting portion 210a of the second main connector which has gear teeth formed along the periphery of the inner side surface forming the inner region on the upper portion for providing insertion of the first main connector 111d and connection with it, a shaft insertion portion 210b which is formed on the lower portion of the connecting portion 210a of the second main connector so that the upper end of the main gear shaft 212 is inserted therein, and a fastener insertion portion 210c which is formed between the connecting portion 210a of the second main connector and the shaft insertion portion 210b so that the fastener (not shown) is inserted therein.

The second main connector 210 rotates integrally with the main gear shaft 212 and the first main connector 11Id and transmits rotation forward.

Since the second main connector 210 is connected to the main gear shaft 212 by a fastener (not shown), the second main connector 210 can be separated from the main gear shaft 212 to be separated from the upper plate 22 of the casing in an upward direction.

The second reverse rotation connector element 220 includes a connector support body 221 formed in the shape of a circular plate, a bearing insertion portion 223 which projects upward from the center of the connector support body 221, a second reverse rotation connector 224 which projects upward from the upper bearing insertion portion 223, and a bearing support portion 225 which projects downward from the lower surface of the connector support body 221, so that the fifth bearing 272 is inserted therein and supported.

The connecting sections 222a and 222b of the connector are formed along the periphery of the edge of the supporting body 221 of the connector to ensure connection with the ring gear 240. The connecting sections 222a and 222b of the connector can be made in the form of openings passing, for example, through the supporting body 221 of the connector, and include a first connecting section 222a of the connector connected to the fastening element, and a second connecting section 222b of the connector, which serves as a guide when making the connection with the ring gear 240.

The second reverse rotation connector 224 has gear teeth formed along the periphery of the outer side surface and is connected to the first reverse rotation connector 125g to transmit reverse rotation thereto.

The section 223 for inserting the bearing and the second connector 224 of reverse rotation are formed in a cylindrical shape having a hollow inner section, and the second main connector 210 connected to the shaft 212 of the main gear passes through the inner sections of the section 223 for inserting the bearing and the second connector 224 of reverse rotation. In this case, since a gap is formed between the outer side surface of the second main connector 210 and the inner side surfaces of the section 223 for inserting the bearing and the second connector 224 of reverse rotation, the second main connector 210 and the second connector 224 of reverse rotation can rotate in opposite directions.

When the second reverse rotation connector 224 is formed integrally with the second reverse rotation connector member 220 as described above, the number of members can be reduced and the connecting structure of the connector can be simplified.

The ring gear 240 includes an annular gear housing 241, a ring gear connecting portion 242 having gear teeth formed along the periphery of the inner side surface of the gear housing 241, and a plurality of ring gear connecting portions 243a and 243b formed along the periphery of the upper surface of the gear housing 241.

The connecting portions 243a and 243b of the ring gear may be formed in a shape that projects upward from the upper surface of the gear housing 241, for example, and include a first connecting portion 2 43a of the ring gear inserted into the first connecting portion 222a of the connector for connecting with a fastener (not shown), and a second connecting portion 243b of the ring gear inserted into the second connecting portion 222b of the connector for use as a guide.

The shaft 212 of the main gear is formed with a length in the vertical direction, the upper end portion 212a of the shaft 212 of the main gear is inserted into the shaft insertion portion 210b of the second main connector 210 and connected, and the lower end portion 212b of the shaft 212 of the main gear is connected to the shaft 310 of the electric motor 300 and rotates in the forward direction due to the driving of the electric motor 300.

The fastening groove 212g is formed by being recessed downward from the upper surface of the upper end portion 212a. In the state in which the upper end portion 212a is inserted into the shaft insertion portion 210b, a fastening member (not shown) is fixed in the fastening groove 212g through the fastening member insertion portion 210c, so that the main gear shaft 212 and the second main connector 210 are connected in the axial direction.

An upper portion 212c for inserting a bearing, a shaft housing portion 212d, a gear insertion portion 212e, and a lower portion 212f for inserting a bearing are sequentially formed from top to bottom between an upper end portion 212a and a lower end portion 212b.

The fifth bearing 272 is inserted onto the upper portion 212c for inserting the bearing, and between the inner side surface of the bearing support portion 225 and the outer side surface of the upper portion 212c for inserting the bearing, the inner ring of the fifth bearing 272 rotates in the forward direction, and its outer ring rotates in the reverse direction.

The shaft housing section 212d is formed with a diameter larger than the diameter of the upper section 212c for inserting the bearing, and thus a step is formed at the upper end of the edge of the shaft housing section 212d. The inner ring of the fifth bearing 272 is supported by the step of the shaft housing section 212d.

The main gear 213 is inserted into the gear insertion portion 212e to rotate integrally with it. The gear insertion portion 212e is formed with a diameter smaller than the diameter of the shaft housing portion 212d, and thus a step is formed at the lower end of the edge of the shaft housing portion 212d. When the main gear 213 is inserted into the gear insertion portion 212e, the upper surface of the main gear 213 engages with the step at the lower end of the shaft housing portion 212d, and thus the insertion depth of the main gear 213 is limited.

The sixth bearing 273 is inserted onto the lower portion 212f for inserting the bearing, and since the lower portion 212f for inserting the bearing is formed with a diameter smaller than the diameter of the portion 212e for inserting the gear, a step is formed at the lower end of the edge of the portion 212e for inserting the gear. When the sixth bearing 273 is inserted onto the lower portion 212f for inserting the bearing, the sixth bearing 273 is engaged with the step of the portion 212e for inserting the gear, and thus the insertion depth of the sixth bearing 273 is limited.

The gearbox housing 250 includes an upper housing element 251 made in the form of a disk and located on the upper portion of the gearbox housing 250, a side housing element 252 that extends downwards from the edge of the upper housing element 251, a fastening projection 254 made in the form of a plurality of fastening projections 254 along the outer periphery of the side housing element 252 and having a length in the vertical direction, a central housing flange 255 that projects upwards from the upper housing element 251 on the central portion of the upper housing element 251, a through hole 253 formed to pass through the central portion of the central housing flange 255, and a bearing support portion 256 that projects downwards from the lower surface of the upper housing element 251 in the direction opposite to the central housing flange 255.

A fastening portion 28 (see Fig. 3) fixed to a fastening projection 254 is formed on the upper plate 22 of the casing, and by fixing the fastening projection 254 and the fastening portion 28 to each other using a fastening element (not shown), the gear unit 200 is fixed to the upper plate 22 of the casing.

The second main connector 210 on the inner side and the second reverse rotation connector 224 on the outer side are connected so as to have a coaxial structure and are designed to pass through the through hole 253.

The fourth bearing 271 is disposed between the bearing insertion portion 223 of the second reverse rotation connector 224 and the bearing support portion 256, and the inner ring of the fourth bearing 271 rotates in the reverse direction together with the bearing insertion portion 223.

The cover 260 of the gearbox housing is designed to close the open lower section of the gearbox housing 250 and includes a cover housing 265 made in the form of a flat plate, a section 261 for inserting the main shaft, which is formed on the central section of the cover housing 265 and simultaneously projects upward from the upper surface of the cover 260 of the gearbox housing and projects downward from its lower surface to have a cylindrical shape, an opening 263 for inserting the auxiliary gear shaft, formed in the form of a plurality of openings 263 for inserting the auxiliary gear shaft on the outer periphery of the section 261 for inserting the main shaft, for passing through the cover housing 265, a section 264 for inserting the auxiliary gear shaft, which projects downward from the lower surface of the cover housing 265 and surrounds the opening 263 for inserting the auxiliary gear shaft, and a plurality of fastening flanges 262, which project outward from the edge of the cover housing 265.

A bearing support portion 261a is formed on a lower end portion of a portion 261 for inserting a main shaft for bending inward and projecting, and a shaft passage hole 261b through which a lower end portion 212b of a main gear shaft 212 passes is formed on a central portion of the bearing support portion 261a.

The sixth bearing 273 is arranged between the inner side surface of the main shaft insertion portion 261 and the outer side surface of the lower bearing insertion portion 212f of the main gear shaft 212, so that the main gear shaft 212 rotates in the forward direction. In this case, the lower end portion of the outer ring of the sixth bearing 273 is supported by a step formed on the upper surface of the bearing support portion 261a.

The mounting hole 262a is formed in the mounting flange 262, and by arranging the mounting hole 262a to correspond with the mounting groove (not shown) formed in the lower surface of the mounting projection 254 of the gear housing 250, and then fixing the gear housing 250 and the gear housing cover 260 using the fastener, the gear housing 250 and the gear housing cover 260 are connected to each other.

The connecting structure of the first auxiliary gear 230-1, the second auxiliary gear 230-2 and the third auxiliary gear 230-3 will be described. Since all of the first to third auxiliary gears 230-1, 230-2 and 230-3 are connected using the same structure, the structure will be described only with respect to the first auxiliary gear 230-1.

The first auxiliary gear 230-1 is mounted with the possibility of rotation on the cover 260 of the gearbox housing by means of the shaft 231-1 of the first auxiliary gear, the seventh bearing 232-1 and the fourth retaining ring 233-1.

The first auxiliary gear 230-1 includes a section 230-1a for engaging the main gear, having gear teeth formed along the periphery of the outer peripheral surface, for engaging with the main gear 213, a section 230-1b for engaging the ring gear, located on the upper section of the section 230-1a for engaging the main gear to form a single unit with it, and having gear teeth formed along the periphery of the outer peripheral surface for engaging with the connecting section 242 of the ring gear on the inner side surface of the ring gear 240, and a through section 230-1c of the shaft, formed for vertically passing through the center of the section 230-1a for engaging the main gear and the section 230-1b for engaging the ring gear.

In this case, since the main gear engaging section 230-1a is formed with a diameter larger than the diameter of the ring gear engaging section 230-1b, the number of teeth of the gear of the main gear engaging section 230-1a is larger than the number of teeth of the gear of the ring gear engaging section 230-1b.

When the number of teeth of the gear section 230-1a for engaging the main gear and the number of teeth of the gear section 230-1b for engaging the ring gear are made different from each other as described above, since the rotation speed of the first knife 110 and the rotation speed of the second knife 120 become different from each other, the blender can meet various purposes in grinding food, and thus the sales potential of the blender can be increased.

In the present invention, since the sections 230-1b, 230-2b and 230-3b for engaging the ring gear of the auxiliary gear that transmits reverse rotation are formed internal with respect to the inner side surface of the ring gear 240, the rotation speeds of the first knife 110 and the second knife 120 can be changed in different ranges even without increasing the size of the blender 1.

In particular, since the main gear engaging portion 230-1a and the ring gear engaging portion 230-1b are arranged vertically on top of each other and there is a difference between the height at which the main gear engaging portion 230-1a engages with the main gear 213 and the height at which the ring gear engaging portion 230-1b engages with the ring gear 240, the size of the auxiliary gears 230-1, 230-2 and 230-3 is less limited.

That is, as shown in Fig. 9, since the lower surface of the connecting portion 242 of the ring gear 240 and the upper surface of the main gear engaging portion 230-1 are located at a distance H from each other in the vertical direction which is the direction of the central axis of the main gear shaft 212, the size of the main gear engaging portion 230-1a 230-1 can be increased so that the outer side surface 230-1f of the main gear engaging portion 230-1a of the auxiliary gear 230-1 is located further outward than the inner side surface 244 of the ring gear 240. In this way, by adjusting the auxiliary gear 230-1 to different sizes, the difference in rotational speed between the first knife 110 and the second knife 120 can be made to have different values in a wide range.

The inner peripheral surfaces of the main gear engaging portion 230-1a and the ring gear engaging portion 230-1b, which surround the through shaft portion 230-1c, are formed in a stepped shape, so that the inner peripheral surface of the ring gear engaging portion 230-1b projects further inward than the inner peripheral surface of the main gear engaging portion 230-1a, and thus the stepped portion 230-ld is formed on the inner peripheral surfaces.

A groove 230-1e for inserting a ring, into which a fourth retaining ring 233-1 is inserted, is formed on the inner peripheral surface of the section 230-1a for engaging the main gear.

The shaft 231-1 of the first auxiliary gear includes a section 231-1a for inserting a bearing, on which the seventh bearing 232-1 is inserted, a section 231-1b for inserting a cover, which extends downwardly from the lower end of the section 231-1a for inserting a bearing and has a diameter smaller than the diameter of the section 231-1a for inserting a bearing, and an upper section 231-1c, which is formed on the upper section of the section 231-1a for inserting a bearing and has a diameter larger than the diameter of the section 231-1a for inserting a bearing. The shaft 231-1 of the first auxiliary gear is inserted into the through section 230-1c of the shaft for vertically passing through the through section 230-1c of the shaft.

The seventh bearing 232-1 is disposed between the outer peripheral surface of the shaft 231-1 of the first auxiliary gear and the inner peripheral surface of the portion 230-1a for engaging the main gear, so that the first auxiliary gear 230-1 rotates in the opposite direction relative to the shaft 231-1 of the first auxiliary gear. In this case, the upper end of the outer ring of the seventh bearing 232-1 is engaged with the stepped portion 230-ld, and the lower end of the outer ring of the seventh bearing 232-1 is supported by the fourth retaining ring 233-1.

The section 231-1b for inserting the cover of the shaft 231-1 of the first auxiliary gear is inserted into the hole 263 for inserting the auxiliary gear shaft, and the lower end surface of the section 231-1a for inserting the bearing is engaged with the stepped section 264a of the section 264 for inserting the auxiliary gear shaft. In this case, the section 231-1b for inserting the cover and the hole 263 for inserting the auxiliary gear shaft are connected to each other by a screw connection.

Since the portion 264 for inserting the auxiliary gear shaft projects from the lower surface of the cover housing 265, the vertical thickness of the portion 264 for inserting the auxiliary gear shaft is thicker than the thickness of the cover housing 265. Therefore, since the length with which the portion 231-1b for inserting the cover is inserted into the hole 263 for inserting the auxiliary gear shaft and comes into contact with it can be sufficiently ensured, the verticality can be ensured to prevent the first auxiliary gear shaft 231-1 from tilting relative to the vertical center line when the first auxiliary gear shaft 231-1 is mounted on the cover 260 of the gear housing.

The second auxiliary gear 230-2 is mounted with the possibility of rotation on the cover 260 of the gearbox housing by means of the shaft 231-2 of the second auxiliary gear, the eighth bearing 232-2 and the fifth retaining ring 233-2, each of which is identical to the corresponding element connected to the first auxiliary gear 230-1 described above.

The third auxiliary gear 230-3 is mounted with the possibility of rotation on the cover 260 of the gearbox housing by means of the shaft 231-3 of the third auxiliary gear, the ninth bearing 232-3 and the sixth retaining ring 233-3, each of which is identical to the corresponding element connected to the first auxiliary gear 230-1 described above.

As shown in Fig. 10, the main gear shaft 212 is disposed on the central portion of the reducer housing 250, and the first auxiliary gear shaft 231-1, the second auxiliary gear shaft 231-2 and the third auxiliary gear shaft 231-3 are disposed at an interval of 120° at positions near the periphery of the main gear shaft 212.

The connecting structures of the first main connector 111d, the second main connector 210, the first reverse rotation connector 125g and the second reverse rotation connector 224 will be described with reference to Fig. 6.

The first main connector 111d is formed in the form of a hexagonal rod having a hexagonal cross-section. That is, six flat surface sections 111d-1 and 111d-2 are formed along the periphery of the outer side surface of the main knife shaft 111 on the side surface of the main knife shaft 111, and corner sections 111d-3 are formed between the flat surface sections 111d-1 and 111d-2, which are adjacent to each other. Since the gear teeth consist of peaks and valleys, the corner sections 111d-3 correspond to the peaks of the gear teeth, and the flat surface sections 111d-1 and 111d-2 correspond to the valleys of the gear teeth.

The diameter of the first main connector 11Id must be large to form the first main connector 111d in polygonal shapes with a greater number of sides than a hexagon. However, by forming the first main connector 111d in the shape of a hexagonal rod, the first main connector 111d can be made with a small diameter.

In the connecting portion 210a of the second main connector 210, into which the first main connector 111d is inserted, a plurality of peaks and valleys are alternately and repeatedly formed along the periphery of the inner side surface, so that gear teeth are formed. When the corner portions 111d-3 are inserted into the valleys of the connecting portion 210a of the second main connector and rotate, the corner portions 111d-3 are engaged with the peaks of the connecting portion 210a of the second main connector, so that the corner portions 111d-3 and the connecting portion 210a of the second main connector rotate together.

In the case in which the first main connector 111d is formed with six corner portions 111d-3 to realize the first main connector 111d with a small diameter, when the number of depressions of the connecting portion 210a of the second main connector formed on the second main connector 210 is formed, for example, in a quantity of twelve, and thus is formed larger than the number of corner portions 111d-3, since the tops and depressions can be connected regardless of the direction in which the first main connector 111d is inserted into the connecting portion 210a of the second main connector, the work of assembling the first main connector 111d and the second main connector 210 is facilitated.

Although the first main connector 111d has been described above as being inserted into the inner region of the second main connector 210 and engaged with the inner region of the second main connector 210, when the positions of the gear teeth formed on the first main connector 111d and the second main connector 210 are changed, that is, the gear teeth of the first main connector 111d are formed on its inner side surface, and the gear teeth of the second main connector 210 are formed on its outer side surface, the second main connector can be inserted into the inner region of the first main connector and engaged with the inner region of the first main connector.

The number of teeth of the gear of the first reverse rotation connector 125g and the number of teeth of the gear of the second reverse rotation connector 224 can be made the same.

In the present embodiment, as described above, the second reverse rotation connector 224 is inserted into the inner region of the first reverse rotation connector 125g and is engaged with the inner region of the first reverse rotation connector 125g, but when changing the positions of the gear teeth formed on the second reverse rotation connector 224 and the first reverse rotation connector 125g, that is, the gear teeth of the second reverse rotation connector 224 are formed on its inner side surface, and the gear teeth of the first reverse rotation connector 125g are formed on its outer side surface, the first reverse rotation connector can be inserted into the inner region of the second reverse rotation connector and engaged with it.

As shown in Fig. 8, since the first main connector 111d is inserted into the inner region of the second main connector 210 and engaged therewith, and on its outer side the second reverse rotation connector 224 is inserted into the inner region of the first reverse rotation connector 125g and engaged therewith, the four connectors are connected in a coaxial structure.

In addition, the portion in which the first main connector 111d and the second main connector 210 are engaged with each other, and the portion in which the first reverse rotation connector 125g and the second reverse rotation connector 224 are engaged with each other, may be configured to at least partially overlap with each other in a vertical direction, which is an axial direction.

Thus, since the height of the recessed portion 25 for connecting the four connectors can be minimized, the size of the blender 1 can be reduced.

In the blender 1 having the above-mentioned structure, when the electric motor 300 is driven, the main gear shaft 212, the main gear 213, the second main connector 210, the first main connector 111d, the main knife shaft 111 and the first knife 110, which are connected to the shaft 310 of the electric motor 300, rotate in the forward direction.

At the same time, the first to third auxiliary gears 230-1, 230-2 and 230-3, which are engaged with the main gear 213, and the ring gear 240, engaged with the first to third auxiliary gears 230-1, 230-2 and 230-3, rotate in the reverse direction. Thus, the forward rotation of the main gear 213 is converted into reverse rotation.

Due to the reverse rotation of the ring gear 240, the second reverse rotation connector 224, the first reverse rotation connector 125g, the reverse rotation knife shaft 125, the second cover 121 and the second knife 120 rotate in the reverse direction.

As described above, since in the recessed portion 25, which is a region formed between the container 10 and the casing 20, the first main connector 111d and the second main connector 210 are connected to each other, and the first reverse rotation connector 125g and the second reverse rotation connector 224 are connected to each other, when the container 10 is separated from the casing 20, only the blade unit 100 remains connected to the container 10, and the reducer unit 200 remains inside the casing 20. Therefore, since the container 10 connected to the blade unit 100 is light, inconvenience to the user due to the weight of the container 10 can be prevented.

In addition, since the blade unit 100 can be easily detached from the container 10, the container 10 and the blade unit 100 can be washed in a position in which the blade unit 100 is removed from the container 10. In this way, it is possible to prevent injury to the user due to the blade when washing the container 10 and the blade unit 100.

In addition, when the container 10 and the knife unit 100 are separated from the casing 20, since the second main connector 210 is open to the upper side of the upper plate 22 of the casing 20, the second main connector 210 can be easily separated from the reducer unit 200. Therefore, separate washing of the second main connector 210 is facilitated.

The embodiments of the present invention have been described in detail above, but the present invention is not limited to the embodiments described above. The present invention can be modified and implemented in various other ways within the scope of the claims, detailed description and accompanying drawings, and such modifications also relate to the present disclosure.

Description of reference positions

10: container 11: container body

12: Bottom section 13: Bottom flange of container

14: Through hole 15: Through hole flange

20: casing 21: case body

22: Upper plate of the casing 22a: Through hole

24: container installation section 25: recessed section

26: Recessed section wall body 27: Casing cover

100: knife assembly 100a: knife set

110: first knife 110a: shaft connecting section

110b: knife section 110c: shaft through hole

111: Main knife shaft 111a: First knife connecting section

111b: shaft housing 111c: protruding step

111d: first main connector 112: first cover

120: second knife 120a: shaft connecting section

120b: knife section 120c: shaft through hole

120d: knife connecting surface 121: second cover

121a: lid body 121b: lid upper surface section

121c: screw thread 121d: through hole

125: Reverse rotation knife shaft 125a: Shaft housing section

125b: connecting section of the second knife 125c: protruding support section

125d: section of the upper shaft housing 125e: groove for inserting the first ring

125f: groove for inserting the second ring 125g: first reverse rotation connector

125h: shaft through hole 130: holder

131: Holder section 131a: Through hole

132: edge section 133: support section

134: Groove for inserting the third ring 142: First oil seal

143: first bearing 144: second bearing

145: Second oil seal 146: Third bearing

150: sealing element 160: fastening nut

160a: Nut body section 160b: Through hole

160 s: outer flange 171: first retaining ring

172: Second retaining ring 173: Third retaining ring

174: Ring bushing 200: Gearbox assembly

200a: auxiliary reducer unit 210: second main connector

210a: Second main connector connection section

210b: Shaft insertion section

210 s: Fastener insertion area

212: Main gear shaft

212a: upper end section 212b: lower end section

212c: Upper section for bearing insertion 212d: Shaft housing section

212e: Gear insertion area

212f: lower section for bearing insertion

212g: mounting groove 213: main gear

220: Second reverse rotation connector element

221: connector support body

222a, 222b: Connector connection section 223: Bearing insertion section

224: Second reverse rotation connector 225: Bearing support section

230-1: first auxiliary gear 230-1a: main gear engagement section

230-1b: section for engagement of ring gear 231-1: shaft of first auxiliary gear

232-1: Seventh bearing 233-1: Fourth retaining ring

230-2: Second auxiliary gear 231-2: Second auxiliary gear shaft

232-2: eighth 233-2: fifth retaining ring

230-3: third auxiliary gear 231-3: third shaft

auxiliary gear

232-3: ninth bearing 233-3: sixth retaining ring

240: Ring gear 241: Gear housing

242: Ring gear connecting section

243a, 243b: connecting section of ring gear

244: inner side surface 250: gearbox housing

251: Upper body element 252: Side body element

253: Through hole 254: Mounting lug

255: Central flange of housing 2 56: Bearing support section

260: Gearbox housing cover 261: Main shaft insertion section

262: Mounting flange 263: Auxiliary gear shaft insertion hole

264: Auxiliary gear shaft insertion section

265: Lid body

271: fourth bearing 272: fifth bearing

273: sixth bearing 300: electric motor

Claims (58)

1. A blender with bidirectionally rotating blades, comprising a blade assembly including a main blade shaft, which is configured to provide integral rotation of a first blade and a first main connector in a forward direction, and a reverse rotation blade shaft, which is configured to provide integral rotation of a second blade and a first reverse rotation connector in a reverse direction and has a structure that is coaxial with the main blade shaft and through which the main blade shaft passes; and a gearbox assembly including a main gear shaft which is configured to provide rotation of a second main connector which is engaged with the first main connector and the main gear in a forward direction, at least one auxiliary gear which is engaged with the main gear and rotates in the reverse direction, a ring gear for which the auxiliary gear is internal and engaged with it, and a second reverse rotation connector which is configured to rotate integrally with the ring gear in the reverse direction and transmit the reverse rotation to the first reverse rotation connector, at the same time in the inner region of one of the first main connector and the second main connector, the other of the first main connector and the second main connector is inserted to engage therewith; the first reverse rotation connector is formed as a single piece with the lower end section of the reverse rotation knife shaft; one of the first reverse rotation connector and the second reverse rotation connector is inserted into the inner region of the other of the first reverse rotation connector and the second reverse rotation connector and engaged therewith, in a casing having a reducer unit located therein, there are located a container mounting section, which is formed along the periphery of the upper end of the casing and on which a container for placing food products is located, a recessed section wall body, which extends downwards from an inner side end section of the container mounting section, and a casing top plate, which extends inwards from the lower end of the recessed section wall body and is formed in a position below the container mounting section; in the recessed portion, which is an inner region surrounded by the recessed portion wall body and the casing top plate, the first main connector and the second main connector are connected to each other, and the first reverse rotation connector and the second reverse rotation connector are connected to each other; the second main connector is connected to the upper end of the main gear shaft using a fastener, and after separating the fastener from the second main connector and the main gear shaft at a position in which the container is separated upward from the casing, the second main connector is separated from the main gear shaft to an upper side of the upper plate of the casing; the knife assembly is mounted to pass through the lower portion of the food container and is detachably connected to the container; and When separating the casing, which has a gear unit installed in it, from the container, the gear unit is separated from the knife unit. 2. The blender according to claim 1, wherein the auxiliary gear includes a section for engaging the main gear, engaged with the main gear, and a section for engaging the ring gear, which is vertically located on the section for engaging the main gear, made integral with it and engaged with the inner side surface of the ring gear. 3. The blender according to claim 2, wherein the number of teeth of the gear section for engaging the main gear and the number of teeth of the gear section for engaging the ring gear differ from each other. 4. The blender according to claim 2, wherein the outer side surface of the section for engaging the main gear is located further outward than the inner side surface of the ring gear. 5. The blender according to claim 2, wherein the lower surface of the connecting section of the ring gear, on which the teeth of the ring gear are formed, and the upper surface of the section for engaging the main gear are located at a distance from each other in the direction of the central axis of the main gear shaft. 6. The blender according to claim 1, wherein the second reverse rotation connector is formed as a single piece with the support body of the connector of the element of the second reverse rotation connector connected to the ring gear, and has a shape that projects upward from the central section of the support body of the connector. 7. The blender according to item 6, in which a plurality of connecting sections of the ring gear are formed along the periphery of the annular body of the ring gear; and the connector support body is formed in the shape of a disk, and the connector connection section is formed on the periphery of the edge of the connector support body to ensure connection with the connection section of the ring gear. 8. The blender according to item 1, additionally containing a gearbox housing configured to surround a portion of the outer side of the gearbox assembly; and a gearbox housing cover designed to close the open section of the gearbox housing. 9. The blender according to item 8, additionally containing an auxiliary gear shaft which is inserted into a through section of the auxiliary gear shaft formed to pass vertically through the central section of the auxiliary gear, and has a lower section connected by a screw connection to a hole for inserting the auxiliary gear shaft formed in the cover of the gearbox housing; a bearing disposed between the inner side surface of the auxiliary gear and the outer side surface of the auxiliary gear shaft, so that the auxiliary gear rotates relative to the auxiliary gear shaft; and a retaining ring inserted into a ring insert groove formed along the periphery of the inner side surface of the auxiliary gear to support the lower surface of the bearing. 10. The blender according to item 8, in which a through hole is formed to pass through the upper element of the housing, which is located on the upper section of the gearbox housing; and the second main connector and the second reverse rotation connector are coaxial and pass through the through hole. 11. The blender according to item 8, in which the bearing support section, into which the bearing is inserted, is formed on the lower surface of the upper element of the housing located on the upper section of the gearbox housing; and the bearing is located between the bearing support section and the bearing insert section, which is formed integrally with the lower section of the second reverse rotation connector. 12. The blender according to item 8, in which the auxiliary gear shaft is designed to pass vertically through the center of the auxiliary gear; the gearbox housing cover includes a cover body made in the form of a flat plate; a section for inserting the auxiliary gear shaft, which is formed thicker than the cover body and has a hole formed therein for inserting the auxiliary gear shaft, formed as a single piece with the cover body; and the lower end portion of the auxiliary gear shaft is inserted into the auxiliary gear shaft insertion hole and supported by it. 13. The blender of claim 1, wherein the first main connector and the second main connector are located within the first reverse rotation connector and the second reverse rotation connector. 14. The blender of claim 1, wherein a gap is formed between the outer side surface of the second main connector and the inner side surface of the second reverse rotation connector to ensure rotation of the second main connector and the second reverse rotation connector in opposite directions. 15. The blender according to item 1, in which the first main connector is formed integrally with the lower end section of the main knife shaft; and one of the first main connector and the second main connector is inserted into the inner region of the other of the first main connector and the second main connector and engaged therewith. 16. The blender according to item 1, in which the first main connector, the second main connector, the first reverse rotation connector and the second reverse rotation connector are coaxial; and a section in which the first main connector and the second main connector are engaged with each other, and a section in which the first reverse rotation connector and the second reverse rotation connector are engaged with each other with at least partial overlapping of each other in the axial direction of the main knife shaft. 17. The blender according to item 1, in which in the inner region of one of the first main connector and the second main connector, the other of the first main connector and the second main connector is inserted to engage therewith; and the number of peaks and valleys formed on a connector having an internal region formed therein is greater than the number of peaks and valleys formed on another connector. 18. The blender according to item 1, in which a through hole through which the second main connector and the second reverse rotation connector pass is formed in the top plate of the casing; and the section of the top plate of the casing in which the through hole is made protrudes further upward than the edge of the outer side of the top plate of the casing. 19. The blender according to claim 1, wherein at least two bearings, which are arranged vertically at a distance from each other to ensure rotation relative to each other, are located between the outer side surface of the main knife shaft and the inner side surface of the reverse rotation knife shaft. 20. A blender according to item 1, which is equipped with a holder including a holder portion through which the main knife shaft and the reverse rotation knife shaft pass, an edge portion that extends outward along the periphery of the holder portion, and a cylindrical support portion that projects downward from a lower surface of the holder portion; and the support section passes through the lower section of the container, and the sealing element is configured to maintain air tightness between the lower surface of the edge section and the upper surface of the container. 21. A blender according to item 1, which is equipped with a holder including a holder section through which the main knife shaft and the reverse rotation knife shaft pass, an edge section that extends outwardly along the periphery of the holder section, and a cylindrical support section that projects downwardly from the lower surface of the holder section; and the support section passes through the lower section of the container, and the fastening nut is designed with the possibility of a screw connection with the outer side surface of the support section for connecting the knife assembly to the lower side of the container.