JP2020175099A - Warmth-retaining cup capable of outputting water quantitatively - Google Patents

Abstract

To provide a warmth-retaining cup capable of outputting water quantitatively.SOLUTION: The warmth-retaining cup comprises a cup body and a water storage chamber which is formed in the cup body and communicates with the outside. A sealing cover is hinged to an opening of the water storage chamber, an isolation block is slidably arranged in the water storage chamber, and a first transmission chamber is formed in the isolation block. The warmth-retaining cup according to the present invention can quantitatively output water during drinking, and quickly perform stirring after the water is output, so that hot water is cooled quickly to a proper temperature to afford convenience to a person who drinks water.SELECTED DRAWING: Figure 1

Description

The present invention is related to the cup field, and specifically, it is a heat-retaining cup that allows water to flow out quantitatively.

When people drink water with a heat-retaining cup, the heat-retaining effect of the heat-retaining cup makes it impossible to drink the hot water in the cup immediately, and at the same time, ordinary heat-retaining cups have difficulty controlling the outflow of water, so the above In order to solve the problem, there is a strong demand for a heat-retaining cup that allows water to flow out quantitatively.

Chinese Patent Application Publication No. 10838644

An object of the present invention is to provide a heat-retaining cup that allows water to flow out quantitatively, eliminate the above-mentioned drawbacks in the existing technology, and enhance the practicality of the equipment.

The heat-retaining cup through which the water of the present invention can flow out quantitatively includes a cup main body and a water storage chamber installed in the cup main body and communicating with the outside, and a sealing lid is hinged at the opening of the water storage chamber. A partition block is slidably installed in the water storage chamber, a first transmission chamber is installed in the partition block, and a second transmission chamber is installed in the left end wall of the first transmission chamber. A transmission chamber is installed, a slide chamber is installed in the left end wall of the second transmission chamber, a slide block is slidably installed in the slide chamber, and the end of the slide block and the slide chamber. The first return device is elastically installed between the wall and the right end wall of the slide block, the motor is fixedly installed in the right end wall of the slide block, and the end extending to the right of the output shaft of the motor. A first capscrew is fixedly installed, a centrifugal chamber is installed in the top wall of the first transmission chamber, and a rotary sleeve is rotatably installed between the centrifugal chamber and the first transmission chamber. A second capscrew that meshes with the first capscrew is fixedly installed on the outer surface of the rotary sleeve in the first transmission chamber, and is fixedly installed on the outer surface of the rotary sleeve in the centrifugal chamber. A centrifuge is fixedly installed, a slide groove is installed symmetrically in the circumferential wall of the centrifuge, and a centrifuge block is slidably installed in the slide groove. A second return device is elastically installed between the end wall of the slide groove, a rotary chamber penetrating vertically is installed in the rotary sleeve, and an oblique rotation chamber is installed in the inner wall of the rotary chamber. The groove is installed symmetrically in the center, the screw sleeve is rotatably installed in the rotary chamber, and the first slide hole corresponding to the diagonal groove is centrally symmetrically installed in the circumferential wall of the screw sleeve. The first slide rod is slidably installed in the first slide hole, and the first spring is elastically installed between the first slide rod and the end wall of the first slide hole. , Screw holes penetrating vertically are installed in the screw sleeve, screw rods extending vertically are connected by threads in the screw holes, and both upper and lower ends of the screw rods are said. It is fixedly installed on the upper and lower end walls of the water storage chamber, water outflow holes penetrating up and down are installed in the slide block, and the water outflow is in the right end wall of the centrifugal chamber. A second slide hole penetrating the hole is installed, a second slide rod is slidably installed in the second slide hole, and the second slide rod and the end wall of the second slide hole A third return device is elastically installed between them, and a punch hole penetrating vertically is installed in the second slide rod, and the centrifuge plate rotates to interlock the centrifuge block to the outside. The second slide rod is moved and interlocked with the movement of the second slide rod, whereby the withdrawal hole is interlocked and aligned with the water outflow hole, whereby hot water inflow and outflow are realized.

Preferably, a third slide hole is installed in the top wall of the slide chamber, and in the third slide hole, a third slide rod and the third slide rod which are fixedly connected to the slide block. A first rack located above is slidably installed, and a second spring is elastically installed between the first rack and the third slide rod on the top wall of the first rack. A buoyant ball is fixedly mounted, a lock groove is installed in the left end wall of the third slide rod, and a fourth slide hole is installed in the left end wall of the third slide hole. A second rack is slidably installed in the fourth slide hole, a gear chamber is installed so as to communicate between the fourth slide hole and the third slide hole, and the gear chamber is inside the gear chamber. The first rack and the gears meshing with the second rack are rotatably installed, and a fifth slide hole penetrating the fourth slide hole is installed in the left end wall of the third slide hole. A lock rod is slidably installed in the fifth slide hole, and a third spring is elastically installed between the lock rod and the end wall of the fifth slide hole. A wedge-shaped hole is installed in the inside, a stirring shaft is rotatably installed in the top wall of the second transmission chamber, and a third umbrella gear is installed at the end of the stirring shaft in the second transmission chamber. Is fixedly installed, and a plurality of sets of stirring blades are fixedly installed on the outer surface of the stirring shaft, and the equipment uses the buoyancy ball to control the partition block to move it up and down, thereby quantifying. Achieve the outflow of water.

The beneficial effect of the present invention is: The heat-retaining cup of the present invention allows a quantitative amount of water to flow out of the cup when drinking water, and also causes rapid stirring after the water has flowed out, whereby the hot water is quickly brought to an appropriate temperature. It dissipates heat to the extent that it is convenient for people who drink water.

In order to be able to more clearly explain the examples of the present invention or the technical ideas in the existing technology, the following is a brief introduction to the illustrations necessary to describe the examples or the existing technology, and as is clear, the following. The attached figures described are merely examples of a part of the invention, and those skilled in the art can obtain other attached figures based on these attached figures without paying creative labor.

FIG. 1 is a schematic diagram of the overall configuration of a heat insulating cup in which the water of the present invention can flow out quantitatively. FIG. 2 is an enlarged schematic diagram of FIG. 1A. FIG. 3 is an enlarged schematic diagram of B in FIG.

All features disclosed herein, or all methods or steps in the process disclosed, may be combined in any manner other than with and / or steps that exclude each other.

The present invention will be described in detail with reference to FIGS. 1-3 below, and in order to be more convenient for communication, the orientations appearing in the following sentence are defined as follows: The directions described below are up, down, left, right, front and back. It coincides with the up, down, left, right, front and back directions of the projection relationship of itself.

As shown in FIG. 1-3, the heat-retaining cup from which the water of the present invention can flow out quantitatively includes the cup main body 10 and the water storage chamber 11 installed in the cup main body 10 and communicating with the outside. A sealing lid 12 is connected to the opening of the water storage chamber 11 by a hinge, a partition block 26 is slidably installed in the water storage chamber 11, and a first transmission chamber 19 is installed in the partition block 26. The second transmission chamber 21 is installed in the left end wall of the first transmission chamber 19, and the slide chamber 55 is installed in the left end wall of the second transmission chamber 21. A slide block 25 is slidably installed in the 55, and a first return device 24 is elastically installed between the slide block 25 and the end wall of the slide chamber 55, and the right side of the slide block 25 is installed. The motor 23 is fixedly installed in the end wall, and the first hinged screw 22 is fixedly installed at the end extending to the right of the output shaft of the motor 23, and the top of the first transmission chamber 19 is installed. A centrifugal chamber 13 is installed in the wall, and a rotary sleeve 34 is rotatably installed between the centrifugal chamber 13 and the first transmission chamber 19, and the rotary sleeve in the first transmission chamber 19 is installed. A second capscrew 18 that meshes with the first capscrew 22 is fixedly installed on the outer surface of the 34, and a centrifuge 35 is fixedly installed on the outer surface of the rotary sleeve 34 in the centrifuge chamber 13. A slide groove 36 is installed symmetrically in the circumferential wall of the centrifuge 35, and a centrifugal block 37 is slidably installed in the slide groove 36, and the centrifugal block 37 and the slide groove are slidably installed. A second return device 38 is elastically installed between the end wall of the 36 and a rotary chamber 33 penetrating vertically in the rotary sleeve 34, and inside the inner wall of the rotary chamber 33. The diagonal groove 40 is installed symmetrically in the center, a screw sleeve 34 is rotatably installed in the rotary chamber 33, and the circumferential wall of the screw sleeve 34 corresponds to the diagonal groove 40. One slide hole 42 is installed symmetrically in the center, and a first slide rod 39 is slidably installed in the first slide hole 42, and the end wall of the first slide rod 39 and the first slide hole 42. A first spring 41 is elastically installed between them, and a screw hole 56 penetrating vertically is installed in the screw sleeve 34. In the screw hole 56, a screw rod 31 extending vertically is connected by a thread, and both upper and lower ends of the screw rod 31 are fixedly installed on the upper and lower end walls of the water storage chamber 11, and the slide block 25 A water outflow hole 20 penetrating vertically is installed in the inside, and a second slide hole 15 penetrating the water outflow hole 20 is installed in the right end wall of the centrifuge chamber 13. A second slide rod 17 is slidably installed in the second slide hole 15, and a third return device 14 is elastic between the second slide rod 17 and the end wall of the second slide hole 15. A punching hole 16 penetrating vertically is installed in the second slide rod 17, and the centrifuge 35 rotates to move the centrifuge block 37 to the outside, thereby moving the centrifuge block 37 to the outside. The second slide rod 17 is moved and interlocked, whereby the withdrawal hole 16 is interlocked and aligned with the water outflow hole 20, thereby realizing the inflow and outflow of hot water.

Beneficially, a third slide hole 44 is installed in the top wall of the slide chamber 55, and a third slide rod fixedly connected to the slide block 25 in the third slide hole 44. A first rack 43 located above the 50 and the third slide rod 50 is slidably installed, and a second spring 49 is elastic between the first rack 43 and the third slide rod 50. A buoyancy ball 29 is fixedly mounted on the top wall of the first rack 43, a lock groove 54 is installed in the left end wall of the third slide rod 50, and the third slide hole is installed. A fourth slide hole 46 is installed in the left end wall of the 44, a second rack 45 is slidably installed in the fourth slide hole 46, and the fourth slide hole 46 and the third slide are installed. A gear chamber 48 is installed so as to communicate with the hole 44, and a first rack 43 and a gear 47 meshing with the second rack 45 are rotatably installed in the gear chamber 48. A fifth slide hole 57 penetrating the fourth slide hole 46 is installed in the left end wall of the third slide hole 44, and a lock rod 52 is slidably installed in the fifth slide hole 57. A third spring 51 is elastically installed between the lock rod 52 and the end wall of the fifth slide hole 57, and a wedge-shaped hole 53 is installed in the lock rod 52. A stirring shaft 27 is rotatably installed in the top wall of the transmission chamber 21, and a third umbrella gear 30 is fixedly installed at the end of the stirring shaft 27 in the second transmission chamber 21. A plurality of sets of stirring blades 28 are fixedly installed on the outer surface of the stirring shaft 27, and the equipment uses the buoyancy ball 29 to control the partition block 26 to move it up and down, whereby a certain amount of water flows out. To realize.

In the following, the applicant will introduce in detail how to use the heat-retaining cup with reference to Appendix 1-3 and the specific configuration of the heat-retaining cup that allows the water of the present application to flow out quantitatively as described above:

When drinking water using the heat insulating cup of the present invention, the motor 23 is first started, the motor 23 rotates to rotate and interlock the first umbrella gear 22, thereby the second umbrella gear 18 and the rotary sleeve 32. The centrifuge 35 is rotated and interlocked, and the centrifuge 35 is rotated to move the centrifuge block 37 to the outside, thereby moving and interlocking the second slide rod 17, thereby interlocking the drawing holes 16 with water. Aligned with the outflow hole 20, at the same time, the rotary sleeve 32 rotates to rotate and interlock the screw sleeve 34, thereby interlocking the partition block 26 and moving it downward along the screw rod 31. When the hot water below the 26 is pushed to the upper part of the block 26 and the hot water comes into contact with the buoyant ball 29, the buoyant ball 29 moves up under the buoyant action, thereby interlocking the first rack 43 and moving up. At the same time, the first rack 43 moves up and moves the second rack 45 to move down, and the second rack 45 moves down to move the lock rod 52 together. The third slide rod 50 moves up under the action of the second spring 49 at this time, and the slide block 26 moves up at this time, and the centrifuge plate 35 moves up. The rotation is stopped, the second slide rod 17 moves to the left to seal the water outflow hole 20, and at this time, the motor 22 is started, the motor 22 rotates to rotate and interlock the first umbrella gear 22. The second umbrella gear 18, the stirring shaft 27, and the stirring blade 28 are rotationally interlocked, thereby interlocking the stirring to the hot water above the block 26 to dissipate heat, and when the temperature becomes compatible, the user Convenient to drink water, when you finish drinking the hot water above the block 26, the slide block 25 moves down, the equipment returns to the initial state, and after drinking the hot water below the block 26, drink the water. At the time of addition, the motor 23 rotates in the opposite direction to interlock the first umbrella gear 22 and rotate in the opposite direction, thereby interlocking the second umbrella gear 18, the rotary sleeve 32 and the centrifuge 35 in the opposite direction. The centrifuge 35 rotates to move the centrifuge block 37 to the outside, thereby moving and interlocking the second slide rod 17, thereby linking the drawing hole 16 to the position of the water outflow hole 20. At the same time, the rotary sleeve 32 rotates in the opposite direction to interlock the screw sleeve 34 and rotate in the opposite direction, thereby interlocking the blocks 26 and moving upward along the screw rod 31. At this time, hot water is slowly added into the water storage chamber 11, the motor 23 is closed after the water addition is completed, the rotation of the centrifuge 35 is stopped, the second slide rod 17 moves to the left, and the water outflow hole 20 is sealed. And complete the watering.

From the above detailed analysis, it was found that the heat-retaining cup of the present invention can allow water to flow out from the cup in a quantitative manner when drinking water, and after the water has flowed out, it is swiftly stirred, whereby the hot water is quickly and appropriately flown. It dissipates heat to a temperature that is convenient for people who drink water.

The above is merely a specific embodiment of the invention, and the scope of protection of the invention is not limited to this, and any change or replacement that can be conceived without the passage of creative labor is the protection of the invention. Should be included in the range. Therefore, the scope of protection of the invention should be based on the scope of protection limited to the claims.

Claims (2)

A cup main body and a water storage chamber installed in the cup main body and communicating with the outside are included, a sealing lid is connected by a screw at the opening of the water storage chamber, and a block is separated in the water storage chamber. Slidingly installed, the first transmission chamber is installed in the partition block, the second transmission chamber is installed in the left end wall of the first transmission chamber, and the left end of the second transmission chamber is installed. A slide chamber is installed in the wall, a slide block is slidably installed in the slide chamber, and a first return device is elastically installed between the slide block and the end wall of the slide chamber. The motor is fixedly installed in the right end wall of the slide block, and the first hinged screw is fixedly installed at the end extending to the right of the output shaft of the motor. A centrifugal chamber is installed in the top wall of the transmission chamber, and a rotary sleeve is rotatably installed between the centrifugal chamber and the first transmission chamber of the rotary sleeve in the first transmission chamber. A second capscrew that meshes with the first capscrew is fixedly installed on the outer surface, and a centrifuge is fixedly installed on the outer surface of the rotary sleeve in the centrifuge chamber. A slide groove is installed symmetrically in the peripheral wall, a centrifugal block is slidably installed in the slide groove, and a second return device is installed between the centrifugal block and the end wall of the slide groove. Is elastically installed, a rotary chamber penetrating vertically is installed in the rotary sleeve, and diagonal grooves are installed in the inner wall of the rotary chamber symmetrically in the center, and the inside of the rotary chamber is installed. A screw sleeve is rotatably installed in the screw sleeve, a first slide hole corresponding to the diagonal groove is installed symmetrically in the circumferential wall of the screw sleeve, and a first slide hole is provided in the first slide hole. The slide rod is slidably installed, and the first spring is elastically installed between the first slide rod and the end wall of the first slide hole, and penetrates vertically into the screw sleeve. A screw hole is installed, a screw rod extending vertically is connected by a screw thread in the screw hole, and both upper and lower ends of the screw rod are fixedly installed on the upper and lower end walls of the water storage chamber. A water outflow hole penetrating up and down is installed in the slide block, and a second slide hole penetrating the water outflow hole is installed in the right end wall of the centrifugal chamber. A second slide rod is slidably installed in the second slide hole, and a third return device is elastically installed between the second slide rod and the end wall of the second slide hole. A punch hole penetrating vertically is provided in the second slide rod, and the centrifuge rotates to move the centrifuge block to the outside in an interlocking manner, whereby the second slide rod is moved and interlocked. A heat-retaining cup capable of quantitatively flowing out water, which is characterized in that the drain holes are interlocked with each other to align with the water outflow holes, thereby realizing the inflow and outflow of hot water. A third slide hole is installed in the top wall of the slide chamber, and in the third slide hole, above the third slide rod and the third slide rod which are fixedly connected to the slide block. A first rack located is slidably installed, a second spring is elastically installed between the first rack and the third slide rod, and a buoyancy ball is placed on the top wall of the first rack. Is fixedly mounted, a lock groove is installed in the left end wall of the third slide rod, a fourth slide hole is installed in the left end wall of the third slide hole, and the fourth slide hole is installed. A second rack is slidably installed in the slide hole, a gear chamber is installed so as to communicate between the fourth slide hole and the third slide hole, and the first gear chamber is installed in the gear chamber. A rack and gears meshing with the second rack are rotatably installed, and a fifth slide hole penetrating the fourth slide hole is installed in the left end wall of the third slide hole. A lock rod is slidably installed in the fifth slide hole, and a third spring is elastically installed between the lock rod and the end wall of the fifth slide hole in the lock rod. A wedge-shaped hole is installed, a stirring shaft is rotatably installed in the top wall of the second transmission chamber, and a third umbrella gear is fixed at the end of the stirring shaft in the second transmission chamber. A plurality of sets of stirring blades are fixedly installed on the outer surface of the stirring shaft, and the equipment uses the buoyancy balls to control the separating blocks to move them up and down, whereby a certain amount of water is used. The heat-retaining cup according to claim 1, wherein the water can be quantitatively flowed out.

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