PORTABLE GAS WATER MAKER BASED ON PELTIER THERMOELECTRIC EFFECT, AND WATER-MAKING METHOD THEREOF

Abstract

A portable gas water maker comprises a water maker body with a shell having a hollow structure. A water inlet communicating with the shell and used for injecting water into the shell is formed at an upper end of the water maker body. The water maker body is inverted U-shaped, so that the lower half part of the water maker body is divided into a left cavity and a right cavity. One group of Peltier semiconductor assemblies is arranged in each of the left cavity and the right cavity. A front-end semiconductor and a rear-end semiconductor in each group of Peltier semiconductor assemblies are connected through a wire. The group of semiconductor assemblies in the left cavity is used for generating electricity, and the group of semiconductor assemblies in the right cavity is used for refrigeration.

Claims

1. A portable gas water maker based on Peltier thermoelectric effect, comprising a water maker body with a shell having a hollow structure, wherein a water inlet communicating with the shell and used for injecting water into the shell is formed at an upper end of the water maker body; the water maker body is inverted U-shaped, the lower half part of the water maker body is divided into a left cavity and a right cavity, and both the left cavity and the right cavity communicate with the interior of the water maker body to form a flue for flue gas to flow through; a first group of Peltier semiconductor assemblies and a second group of Peltier semiconductor assemblies are respectively arranged in the left cavity and the right cavity of the water maker body, and a first front-end semiconductor and a first rear-end semiconductor in each of the first and second groups of Peltier semiconductor assemblies are connected through a first wire; a second front-end semiconductor arranged on an inner left side of the left cavity is connected to a second rear-end semiconductor arranged on an inner right side of the right cavity through a second wire, and a third rear-end semiconductor arranged on the inner right side of the left cavity is connected to a third front-end semiconductor arranged on the inner left side of the right cavity through a third wire; the first group of semiconductor assemblies in the left cavity is used for generating electricity, and the second group of semiconductor assemblies in the right cavity is used for refrigeration; a flue gas inlet is formed at a bottom of the left cavity, and a flue gas outlet and a water outlet are formed at a bottom of the right cavity; high-temperature flue gas enters the flue in the water maker body through the flue gas inlet and forms a temperature difference with water in the shell of the water maker body, the first group of Peltier semiconductor assemblies generates electricity through the temperature difference and supplies current to the second group of Peltier semiconductor assemblies for refrigeration, and the high-temperature flue gas in the flue is condensed to obtain liquid water and low-temperature flue gas, and the low-temperature flue gas and the liquid water are discharged through the water outlet and the flue gas outlet.

2. The portable gas water maker based on the Peltier thermoelectric effect according to claim 1, wherein small finned radiators are mounted on each of the first and second groups of Peltier semiconductor assemblies.

3. The portable gas water maker based on the Peltier thermoelectric effect according to claim 1, wherein a filtering device is arranged in a pipeline connecting the flue gas inlet and an interior of the water maker body.

4. The portable gas water maker based on the Peltier thermoelectric effect according to claim 2, wherein a filtering device is arranged in a pipeline connecting the flue gas inlet and an interior of the water maker body.

5. The portable gas water maker based on the Peltier thermoelectric effect according to claim 1, wherein a safety valve communicating with the water maker is arranged at the upper end of the water maker body.

6. The portable gas water maker based on the Peltier thermoelectric effect according to claim 2, wherein a safety valve communicating with the water maker is arranged at the upper end of the water maker body.

7. The portable gas water maker based on the Peltier thermoelectric effect according to claim 1, wherein the water outlet and the flue gas outlet are the same outlet.

8. The portable gas water maker based on the Peltier thermoelectric effect according to claim 2, wherein the water outlet and the flue gas outlet are the same outlet.

9. A water-making method using the portable gas water maker according to claim 5, comprising the following steps: step 1: inspecting tightness of the water maker body and various pipelines, inspecting air tightness and safety of the safety valve, inspecting safety of external fuel gas, and inspecting a connection condition of the first, second and third wires; igniting the external fuel gas after passing the inspection, and introducing high-temperature flue gas into the flue formed in the water maker body through the flue gas inlet; step 2: after the high-temperature flue gas enters the water maker body, forming the temperature difference between the high-temperature flue gas and the water in the shell of the water maker body, then enabling the first group of Peltier semiconductor assemblies to generate electricity, and supplying current to the second group of Peltier semiconductor assemblies to achieve the Peltier thermoelectric effect, to further achieve semiconductor refrigeration; step 3: condensing the high-temperature flue gas in the flue to obtain the liquid water and the low-temperature flue gas, and discharging the low-temperature flue gas out of the portable gas water maker from the flue gas outlet and into the atmosphere; and step 4: enabling the liquid water obtained in step 3 to flow out through the water outlet for users to use.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] FIG. 1 is a structural schematic diagram according to the present invention;

[0029] FIG. 2 is a bottom view according to the present invention;

[0030] FIG. 3 is a front view of a small finned radiator according to the present invention;

[0031] FIG. 4 is a bottom view of a small finned radiator according to the present invention;

[0032] and

[0033] FIG. 5 is a side view of a small finned radiator according to the present invention.

[0034] In the drawings, 1. water maker body; 2. Peltier semiconductor assembly; 3. small finned radiator; 4. water inlet; 5. safety valve; 6. wire; 7. flue gas inlet; 8. flue gas outlet and water outlet.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0035] The specific content of the present invention is further illustrated in detail below with reference to the examples, to which, however, the present invention is not limited.

[0036] As shown in FIG. 1 and FIG. 2, a portable gas water maker based on the Peltier thermoelectric effect comprises a water maker body 1 with a shell having a hollow structure, wherein a water inlet 4 communicating with the shell and used for injecting water into the hollow structure is formed at an upper end of the water maker body 1; the water maker body 1 is inverted U-shaped, so that the lower half part of the water maker body is divided into a left cavity and a right cavity, and both the left cavity and the right cavity communicate with the interior of the water maker body 1 to form a flue for flue gas to flow through.

[0037] One group of Peltier semiconductor assemblies 2 are arranged in each of the left cavity and the right cavity of the water maker body 1, a front-end semiconductor in each group of semiconductor assembly is attached to a left side wall of the cavity where the front-end semiconductor is located, a rear-end semiconductor is attached to a right side wall of the cavity where the rear-end semiconductor is located, and the front-end semiconductor and the rear-end semiconductor in the same cavity are connected through a wire; the front-end semiconductor in the left cavity is connected to the rear-end semiconductor in the right cavity through a wire, and the rear-end semiconductor in the left cavity is connected to the front-end semiconductor in the right cavity through a wire; the group of semiconductor assemblies 2 in the left cavity are used for generating electricity, and the group of semiconductor assemblies 2 in the right cavity are used for refrigeration.

[0038] A flue gas inlet 7 is formed at the bottom of the left cavity, and a filtering device is arranged at the flue gas inlet 7, so that condensed water is cleaner and contains fewer impurities;

[0039] A flue gas outlet and a water outlet 8 are formed at the bottom of the right cavity; high-temperature flue gas enters the water maker body 1 through the flue gas inlet 7 and forms a temperature difference with water in the shell of the water maker body, so that one group of Peltier semiconductor assemblies 2 generates electricity through the temperature difference and supplies current to the other group of Peltier semiconductor assemblies 2 to achieve the Peltier effect, namely semiconductor refrigeration, and the high-temperature flue gas is condensed to obtain liquid water and low-temperature flue gas, and the low-temperature flue gas and the liquid water are discharged through the water outlet and the flue gas outlet.

[0040] Preferably, the water outlet and the flue gas outlet are the same outlet.

[0041] As shown in FIG. 1, FIG. 2, FIG. 3, FIG. 4 and FIG. 5, small finned radiators 3 are mounted on the two groups of Peltier semiconductor assemblies 2, so that heat dissipation of the Peltier semiconductor assemblies 2 can be accelerated, the possibility of the semiconductor assemblies 2 not working normally due to damage caused by high temperature is reduced, and the service life of the water maker is prolonged.

[0042] As shown in FIG. 1, a safety valve 5 is arranged on a water tank shell of the water maker body 1, and the safety valve 5 communicates with the interior of the water tank shell of the water maker body 1 to prevent the water tank shell from failing due to high temperature.

[0043] A water-making method of a portable gas water maker based on the Peltier thermoelectric effect comprises the following steps:

[0044] Step 1: inspecting the tightness of the water maker body 1 and various pipelines, inspecting the air tightness and safety of the safety valve 5, inspecting the safety of external fuel gas, and inspecting the connection condition of wires 6;

[0045] igniting the fuel gas after passing the inspection, and introducing high-temperature flue gas into a flue formed in the water maker body 1 through the flue gas inlet 7;

[0046] Step 2: after the flue gas enters the water maker body 1, forming a temperature difference between the flue gas that is at a very high temperature and the water in the shell of the water maker body 1, then enabling one group of Peltier semiconductor assemblies 2 to generate electricity, and supplying current to the other group of Peltier semiconductor assemblies 2 to achieve the Peltier effect, namely semiconductor refrigeration;

[0047] Step 3: condensing the high-temperature flue gas in the flue to obtain liquid water and low-temperature flue gas, and discharging the low-temperature flue gas out of the water maker from the flue gas outlet and into the atmosphere; and

[0048] Step 4: enabling the liquid water obtained in step 3 to flow out through the water outlet for users to use.

[0049] The present invention works in the following way.

[0050] External high-temperature flue gas is introduced into the flue formed in the water maker body 1 through the flue gas inlet 7, and the high-temperature flue gas forms a temperature difference with the water in the shell of the water maker body, so that one group of Peltier semiconductor assemblies 2 generate electricity through the temperature difference and supply current to the other group of Peltier semiconductor assemblies 2 to achieve the Peltier effect, namely semiconductor refrigeration, and the high-temperature flue gas is condensed to obtain liquid water and low-temperature flue gas, and the low-temperature flue gas is discharged from the flue gas outlet and the liquid water is discharged from the water outlet for users to use.