CN211582521U - Partition heat preservation water cup - Google Patents

Abstract

The utility model provides a partitioned heat-preservation water cup and a water pouring method, wherein the inside of the cup body is partitioned into a heat-preservation area and a drinking area by a middle partition layer, the partition layer is provided with a water filling port which can be opened and closed, the two ends of the cup body are respectively provided with a hot water port and a drinking port which correspond to the heat-preservation area and the drinking area, the hot water port and the drinking port are respectively provided with a heat-preservation cover and a drinking cover, and the heat-preservation areas of the partition layer, the heat-preservation cover and the cup body are all wrapped with heat-preservation layers; the utility model discloses a hot water is sent out to drinking cup heat preservation district memory before needing to drink water, pours into hot water into partly to the drinking water district through the water filling port and cools off, avoids the whole cooling of hot water, can cool off the water yield that needs to drink simultaneously, then realizes when keeping thermos cup totality heat insulating ability, can drink the water of a small cup suitable temperature many times in turn.

Description

Partition heat preservation water cup

Technical Field

The utility model relates to a drinking cup technical field especially relates to an intelligent heat preservation drinking cup of subregion adjustable temperature.

Background

The thermos cup is people's daily necessities, but present thermos cup is mostly absorbed in its heat preservation effect, and has neglected user experience, the user often drinks water a small amount of in batches many times, nevertheless because thermos cup thermal insulation performance is good, lead to the water cooling in the cup slow, only the bowl cover is usually unscrewed cool, not only need long-time waiting, the whole cup of water of time has just all cooled moreover, can't drink then, this drinking water demand that not only can't satisfy people, especially to the huge waste of water resource. Certainly, some intelligent water cups have an automatic heating function, but repeated heating is not only bad for water quality, but also limited by the volume of the water cup, the capacity of a cup-mounted battery is small, and the repeated heating requirement cannot be met; if the resident is heated by electricity, the portability of the water cup is reduced. Users often want to keep the overall heat preservation performance of the vacuum cup and can drink water with a small cup at a proper temperature in batches, and the existing intelligent water cup cannot meet the actual requirement of the users.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve the problem that exists among the prior art, provide an intelligent heat preservation drinking cup of subregion adjustable temperature, can let the volume and the temperature that the user independently selected to drink water and do not worry that whole cup of water all can become cold.

In order to achieve the above object, the utility model provides a technical scheme does: a partitioned heat-preservation water cup comprises a cup body, wherein an interlayer is arranged in the middle of the inside of the cup body and divides the inside of the cup body into a heat-preservation area and a drinking area, a water filling port capable of being opened and closed is arranged on the interlayer, a hot water port and a drinking port corresponding to the heat-preservation area and the drinking area are respectively arranged at two ends of the cup body, a heat-preservation cover and a drinking cover are respectively arranged on the hot water port and the drinking port, and heat-preservation layers are wrapped on the heat-preservation area of the interlayer, the heat-preservation cover and the heat-.

The technical scheme is further designed as follows: temperature sensors are arranged in the heat preservation area and the drinking area.

And water level sensors are arranged in the heat preservation area and the drinking area.

And a microprocessor and a power supply module are arranged in the interlayer, and the power supply module, the temperature sensor and the water level sensor are all connected with the microprocessor.

The cup body is provided with a display screen, and the display screen is connected with the microprocessor.

The cup body is provided with a drinking water temperature setting button, a drinking water amount setting button, a water pouring button and a determining button, and the drinking water temperature setting button, the drinking water amount setting button, the water pouring button and the determining button are all connected with the microprocessor.

A baffle plate, a sliding groove, a push rod, a spring and an electromagnet are arranged in the interlayer, one end of the sliding groove is communicated with the water filling port, the other end of the sliding groove is connected with the electromagnet, and the electromagnet is connected with a power module; the push rod is connected in the sliding groove in a sliding mode, the baffle is fixed to one end of the push rod, one end of the spring is fixed to the baffle, the other end of the spring is fixed to the interlayer, the spring pushes the baffle to one side close to the water filling port, and the push rod is pulled to one side far away from the water filling port after the electromagnet is electrified.

And a heat insulation layer is arranged in the baffle.

The cup body is provided with a USB interface, and the USB interface is connected with a power module.

The utility model has the advantages that:

the utility model discloses separate the drinking cup for heat preservation district and water-drinking district two parts, the heat release water in the heat preservation district, before needing to drink water, pour into some through the water filling port with hot water and cool off to the water-drinking district, avoid the whole cooling of hot water, can cool off the water yield that needs to drink simultaneously. The utility model discloses can keep thermos cup overall heat insulating ability the time, can drink the water of a small cup suitable temperature many times in batches.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a first schematic view of the structure of the septum layer of FIG. 1;

fig. 3 is a schematic diagram of a second barrier layer structure in fig. 1.

In the figure: 1-heat preservation area, 11-heat preservation cover, 2-drinking area, 21-drinking cover, 3-interlayer, 31-water filling port, 32-baffle, 33-spring, 34-sliding groove, 35-push rod, 36-electromagnet, 4-microprocessor and power supply module, 5-display screen, 6-drinking water temperature setting button, 7-drinking water amount setting button, 8-determining button and 9-pouring button.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Examples

As shown in fig. 1, the utility model provides an intelligence drinking cup that keeps warm of subregion adjustable temperature, comprising a cup body, the middle part is equipped with interlayer 3 in the cup, interlayer 3 is heat preservation district 1 and drinking water district 2 with cup internal partitioning, be equipped with the water filling port 31 that can open and close on interlayer 3, the cup both ends are equipped with respectively with heat preservation district 1 and drinking water district 2 corresponding hot water mouth and drinking water mouth, be equipped with heat preservation lid 11 and drinking water lid 21 on hot water mouth and the drinking water mouth respectively, interlayer 2, heat preservation lid 11 and cup all wrap up the heat preservation in heat preservation district 1 part.

In this embodiment, the heat preservation area 1 and the drinking water area 2 are both provided with a temperature sensor and a water level sensor.

Referring to fig. 2 and 3, a microprocessor and a power module 4 are arranged in the interlayer 3, and the power module, the temperature sensor and the water level sensor are all connected with the microprocessor.

And an LED display screen 5 is arranged on the cup body, and the LED display screen 5 is connected with the microprocessor.

The cup body is provided with a drinking water temperature setting button 6, a drinking water amount setting button 7, a water pouring button 9 and a determining button 8, and the drinking water temperature setting button, the drinking water amount setting button, the water pouring button and the determining button are all connected with the microprocessor.

In the embodiment, the drinking water temperature is set by the drinking water temperature setting button 6 and confirmed by the confirming button 8; the water intake setting button 7 sets the water intake and is confirmed by the determination button 8.

The cup body is provided with a USB interface, and the USB interface is connected with the power module and used for charging the power module.

In the embodiment, a baffle 32, a chute 34, a push rod 35, a spring 33 and an electromagnet 36 are arranged in the interlayer 3, one end of the chute 34 is communicated with the water filling port 31, the other end of the chute is connected with the electromagnet 36, the electromagnet 36 is connected with a power module, and the electromagnet 36 generates magnetic force after being electrified; the push rod 35 is made of steel materials and is connected in the sliding groove 34 in a sliding mode, the baffle plate 32 is fixed to one end of the push rod 35, one end of the spring 33 is fixed to the baffle plate 32, and the other end of the spring is fixed to the interlayer 3; in the embodiment, the middle position of the interlayer 3 in the sliding groove 34 is provided with a convex block extending into the sliding groove 34, the other end of the spring 33 is fixed on the convex block, and in a free state, the spring 33 pushes the baffle 32 to one side close to the water filling port 31 to close the water filling port 31; pressing the water pouring button 9 sends a water pouring signal to the microprocessor, the microprocessor sends a signal to the power module, the electromagnet 36 is electrified, and the push rod 35 is pulled to one side far away from the water filling port 31 after the electromagnet 36 is electrified, so that the water filling port 31 is opened.

In this embodiment, a sealing ring is disposed at the connection position of the baffle 32 and the chute 34, and a sealing gasket is disposed at the contact position of the baffle 32 and the inner wall of the water injection port 31.

The heat preservation layer is arranged in the baffle 32 to ensure that the heat preservation area 1 has a good heat preservation effect, and the drinking water area 2 has no heat preservation layer, so that a certain heat dissipation effect is achieved.

The heat preservation district and the water drinking district all are equipped with temperature sensor and level sensor, can show current each regional temperature and water yield through cup LED display screen 5.

In this embodiment, the drinking water temperature sets up the button: the set drinking water temperature is displayed and flickers by the LED display screen 5 after being pressed for 1 time, and the set drinking water temperature can be increased by 1 ℃ by pressing the button once; or the drinking water temperature can be set at T by pressing the button_min℃～T_max(wherein T is)_minDEG C and T_maxThe lowest and highest drinking water temperature which can be set) are circulated, and the temperature is increased by 1 ℃ each time; or the button is pressed for more than S seconds, which indicates that the drinking water temperature is not set, and the default is the actual water temperature of the heat preservation area which is directly used; pressing the confirming button for 1 time to confirm the set drinking water temperature, and stopping flashing the LED;

the water intake sets up the button: according to 1 time, the LED displays the water intake and flickers, and the water intake is initially prompted to be M_minml, the button can be pressed once, delta Xml is increased each time, or the button can be pressed without placing, and the drinking water amount is set to be M_minml～M_maxml (where M is_minml and M_maxml is the lowest and highest water intake that can be set) with each increase of Δ Xml; or the button is pressed for more than S seconds, which indicates that the default drinking water amount is M_minml; pressing the confirming button for 1 time to confirm the set water intake, and stopping flashing the LED;

determining a button: when a long-time button is pressed for more than S seconds in the shutdown state, the system enters the starting state, the liquid level (ml) and the temperature (DEG C) of the heat preservation area and the drinking area are displayed, and the system enters the standby state without operation for delta S seconds; the LED display screen is not displayed in the standby state, the LED display screen is quitted from the standby state according to 1 time, and the LED display screen is lightened to display the liquid level (ml) and the temperature (DEG C) of the heat preservation area and the drinking area; in the system starting state, when an LED display screen displays, long pressing of a determining button exceeds S seconds, prompting to close the system, and if the long pressing is determined again, closing the system; the system has a memory function and can remember the drinking water temperature and the drinking water amount which are set by the user at the last time.

The method for judging the water volume from the heat preservation area to the drinking area according to the required water volume and drinking water temperature, and the water volume and water temperature of the current heat preservation area and the drinking area comprises the following steps:

if the existing water quantity and water temperature of the heat preservation area are respectively A (ml) (when A is<M_min(ml) the display reminds the user to add water in the form of continuous lighting S seconds at intervals of delta H hours) and T₀℃；

The water intake set by the user is B (ml), and if the water intake is not set by the user, the default is M_min(ml), i.e. B ═ M_min；

The drinking water temperature T DEG C (T is less than or equal to T) set by the user₀That is, the drinking water temperature set by the user cannot be higher than the temperature of the water in the heat preservation area), if the drinking water temperature is not set by the user, the actual water temperature in the heat preservation area is defaulted, that is, T is T ═ T₀；

At this time:

1) the drinking area has no water:

a) if there is no water in the drinking area, or very little (less than L)_min(ml)), the equivalent is regarded as no water in the drinking area;

b) if A is not less than B, pouring water into the drinking area according to the water drinking amount set by the user to B (ml);

c) if A is less than B, the water in the heat preservation area is completely filled into the drinking area, and after the water is filled, the water quantity of the drinking area is A (ml);

d) after the operation is finished, the LED screen displays the water quantity and the water temperature of the heat preservation area and the water drinking area in real time, and the LED screen is not operated for delta S seconds and enters a standby state; when the water temperature of the drinking area is reduced to T ℃, the LED screen flickers to prompt a user to drink water.

2) The drinking area has water:

the water quantity and the water temperature of the drinking water area are respectively C (ml) and T₁C is more than or equal to L_min；

The state is divided into two cases in which,

case 1: t is₁T or more, it is higher than the drinking water temperature that the user set up that the existing temperature of water in the explanation drinking water district, directly judge the water yield this moment:

a) if C is larger than or equal to B, the water intake of the drinking area is higher than the water intake set by a user, and water is not injected;

b) if C is less than B, when A is more than or equal to B-C, the water quantity of the heat preservation area is enough, and at the moment, water is filled from the heat preservation area to the drinking area until B (ml);

c) if A is less than B-C, the water in the heat preservation area is completely filled into the drinking area, and after the water is filled, the water amount in the drinking area is C + A (ml);

d) after the operation is finished, the LED screen displays the water quantity and the water temperature of the heat preservation area and the drinking area in real time, the water enters a standby state without operation for delta S seconds, and when the water temperature of the drinking area is reduced to T ℃, the LED screen flickers to prompt a user to drink water.

Case 2: t is₁<T, it shows that the existing water temperature in the drinking area is lower than the drinking water temperature set by the user:

a) if C is larger than or equal to B, calculating and prompting the water quantity D (ml) to be poured out by a user according to a heat balance equation and a final drinking water temperature priority principle so as to enable the final water temperature to be T, then injecting water from the heat preservation area to the drinking area so as to enable the final water temperature to be T, and displaying the water quantities and the water temperatures of the heat preservation area and the drinking area in real time through an LED screen;

b) if C is less than B, calculating and prompting the water quantity E (ml) to be poured by a user according to a heat balance equation and a final drinking water temperature priority principle so as to enable the final water temperature to be T, and then injecting water from the heat preservation area to the drinking area so as to enable the final water temperature to be T; the LED screen displays the water quantity and the water temperature of the heat preservation area and the drinking area in real time;

c) after the operation is finished, the LED screen displays the water quantity and the water temperature of the heat preservation area and the water drinking area in real time, and the LED screen is not operated for delta S seconds and enters a standby state; when the water temperature of the drinking area is reduced to T ℃, the LED screen flickers to prompt a user to drink water.

In the above method, the calculation process of D, E is:

the temperature of water changes to delta t in a certain process, the heat absorbed (or released) by the water is C × m × delta t, wherein c is the specific heat of the water and is a constant, m is the mass of the water and is recorded in ml, and delta t is the change of the water temperature_Put＝Q_{Suction device}：

The calculation process of D is as follows:

according to the formula of heat balance Q_Put＝Q_{Suction device}Based on the principle that the final drinking water temperature is prior to the temperature of the drinking waterTo fall into the following 2 cases:

i. if the amount of water A in the holding area is sufficient, that is, if

Then

The amount of water injected into the drinking water area from the heat preservation area is

After water is injected, the water quantity of the drinking area is B;

the calculation process is as follows:

if the water quantity A of the heat preservation area is enough, namely the water quantity of the final drinking area is B, according to a heat balance formula Q_Put＝Q_{Suction device}Obtaining:

c[B-(C-D)](T₀-T)＝c(C-D)(T-T₁)

thus, it is possible to obtain;

then the water amount poured into the drinking area from the heat preservation area is F ═ B- (C-D), and the D is substituted to obtain

Therefore, the water amount A in the holding zone is enough, that is to say

if the water content A in the holding area is insufficient, i.e. if

Then

The water quantity injected into the drinking water area from the heat preservation area is A, and after water injection, the water quantity in the drinking water area is A

The calculation process is as follows:

if the water quantity A of the heat preservation area is not enough, namely the final drinking water temperature is ensured to reach T, A is completely poured into the drinking water area, and at the moment:

cA(T₀-T)＝c(C-D)(T-T₁)

thus, it is possible to obtain;

the calculation process of E is as follows:

according to the formula of heat balance Q_Put＝Q_{Suction device}On the principle of final drinking water temperature priority, the following 4 cases can be divided:

i. if the water quantity A of the heat preservation area is enough and the existing water quantity C of the drinking area is more, partial water possibly needs to be poured from the drinking area, namely E is more than or equal to 0

The amount of water injected into the drinking water area from the heat preservation area is

After water is injected, the water quantity of the drinking area is B;

the calculation process is as follows:

if the water quantity A of the heat preservation area is enough and the existing water quantity C of the drinking area is more, namely, a certain amount of water is poured after the water in a part of the drinking area is possibly poured, finally the water quantity of the drinking area is B and the water temperature is T, namely E is more than or equal to 0,according to the formula of heat balance Q_Put＝Q_{Suction device}Obtaining:

c[B-(C-E)](T₀-T)＝c(C-E)(T-T₁)

this gives:

because the water quantity C of the drinking area is enough at the moment, E is more than or equal to 0,

and due to C<B，T₁<T<T₀Is obtained by

The water quantity H which is poured into the drinking area from the heat preservation area is B- (C-E), and is substituted into E to obtain the water drinking water

Since the water quantity A in the heat-insulating area is enough, A is more than or equal to H, namely

if calculated in case i

But instead of the other end of the tube

At the moment, the water quantity A in the heat preservation area is insufficient, but the water quantity C in the drinking area is enough, according to the principle that the final drinking water temperature is prior, the water quantity poured out at the moment means that more water in the drinking area is poured out

The water in the heat preservation area is completely injected into the drinking area, and after the water is injected, the water quantity in the drinking area is

And (3) calculating:

if calculated in case i

But instead of the other end of the tube

At the moment, the water quantity A of the heat preservation area is insufficient, but the water quantity C of the drinking area is enough, in this case, the water of the heat preservation area is completely filled into the drinking area, and the heat balance formula Q is used_Put＝Q_{Suction device}Obtaining:

cA(T₀-T)＝c(C-E)(T-T₁)

this gives:

if the amount of water A in the holding area is sufficient, but the amount of water C in the drinking area is insufficient, i.e. if

Then E is 0, that is, the water in the drinking area is not poured, and the amount of water poured into the drinking area from the heat preservation area is

After water injection, the water amount of the drinking area is

And (3) calculating:

if the water quantity A of the heat preservation area is enough, but the water quantity C of the drinking area is insufficient, the water quantity C of the drinking area means that the water in the drinking area cannot be used, namely E is 0, and the method is derived from the formula:

according to the formula of heat balance Q_Put＝Q_{Suction device}Obtaining:

cJ(T₀-T)＝cC(T-T₁)

this gives:

if the water amount in the heat preservation area and the water drinking area is insufficient, at the moment

There are two cases to be distinguished:

if A/C is more than or equal to A '/C', the existing water quantity C of the drinking area is relatively seriously insufficient, and the existing water quantity A of the heat preservation area is more, which means that the existing water in the drinking area cannot be fallen, and the water quantity injected into the drinking area from the heat preservation area is

After water injection, the water amount of the drinking area is

If A/C<A '/C' indicates that the water quantity A in the heat preservation area is relatively seriously insufficient, and the water quantity in the drinking area is more, which means that part of water needs to be poured from the drinking area, namely E>0, water in the heat preservation area is completely filled into the drinking water area, and after water is filled, the water volume of the drinking water area is

And (3) calculating:

if the water quantity of the heat preservation area and the water drinking area is insufficient, the water drinking area is used for drinking water

According to the ideal state, the water in the heat preservation area is just merged with the water in the drinking area to form B (ml) water with the temperature T ℃ set by a user

According to this ratio, the ratio A/C is not less than A '/C' andA/C<two cases of A '/C':

if A/C is more than or equal to A '/C', the existing water quantity C of the drinking area is relatively seriously insufficient, and the water quantity A of the heat preservation area is more, namely the existing water in the drinking area cannot be fallen, namely E is 0, according to a heat balance formula Q_Put＝Q_{Suction device}Obtaining:

cL(T₀-T)＝cC(T-T₁)

this gives:

if A/C<A '/C' indicates that the water quantity A in the heat preservation area is relatively seriously insufficient, and the water quantity in the drinking area is more, which means that part of water needs to be poured from the drinking area, namely E>0, water in the heat preservation area is completely filled into the drinking area according to a heat balance formula Q_Put＝Q_{Suction device}Obtaining:

cA(T₀-T)＝c(C-E)(T-T₁)

this gives:

the technical scheme of the utility model is not limited to above-mentioned each embodiment, and the technical scheme that all adopt to equate substitution mode to obtain all falls the utility model discloses the within range that claims.

Claims (8)

1. The utility model provides a subregion drinking cup that keeps warm, includes the cup, its characterized in that: the cup is characterized in that an interlayer is arranged in the middle of the inside of the cup body and divides the inside of the cup body into a heat preservation area and a drinking water area, a water filling port capable of being opened and closed is arranged on the interlayer, a hot water port and a drinking water port corresponding to the heat preservation area and the drinking water area are respectively arranged at two ends of the cup body, a heat preservation cover and a drinking water cover are respectively arranged on the hot water port and the drinking water port, and heat preservation layers are wrapped on the interlayer, the heat preservation cover and the heat preservation area of the cup.

2. The zoned insulating cup of claim 1, wherein: and temperature sensors and water level sensors are arranged in the heat preservation area and the drinking water area.

3. The zoned insulating cup of claim 2, wherein: and a microprocessor and a power supply module are arranged in the interlayer, and the power supply module, the temperature sensor and the water level sensor are all connected with the microprocessor.

4. The zoned insulating cup of claim 3, wherein: the cup body is provided with a display screen, and the display screen is connected with the microprocessor.

5. The zoned insulating cup of claim 4, wherein: the cup body is provided with a drinking water temperature setting button, a drinking water amount setting button, a water pouring button and a determining button, and the drinking water temperature setting button, the drinking water amount setting button, the water pouring button and the determining button are all connected with the microprocessor.

6. The zoned insulating cup of claim 5, wherein: a baffle plate, a sliding groove, a push rod, a spring and an electromagnet are arranged in the interlayer, one end of the sliding groove is communicated with the water filling port, the other end of the sliding groove is connected with the electromagnet, and the electromagnet is connected with a power module; the push rod is connected in the sliding groove in a sliding mode, the baffle is fixed to one end of the push rod, one end of the spring is fixed to the baffle, the other end of the spring is fixed to the interlayer, the spring pushes the baffle to one side close to the water filling port, and the push rod is pulled to one side far away from the water filling port after the electromagnet is electrified.

7. The zoned insulating cup of claim 6, wherein: and a heat insulation layer is arranged in the baffle.

8. The zoned insulating cup of claim 7, wherein: the cup body is provided with a USB interface, and the USB interface is connected with a power module.

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