JPH0435789A - Production equipment for calcareous water - Google Patents

Abstract

PURPOSE:To economically utilize gaseous carbon dioxide by supplying gaseous carbon dioxide having specified pressure to the gaseous part of the inside of a closed vessel and introducing water as a jet to dissolve gaseous carbon dioxide into water and taking out calcareous water. CONSTITUTION:Gaseous carbon dioxide having specified pressure is blown into a vessel 1 from a gaseous carbon dioxide source 3. When water is introduced as a jet, gaseous carbon dioxide collides against water surface. At this time, gaseous carbon dioxide in the periphery is entrained underwater by viscous force, etc. Thereby gaseous carbon dioxide is dissolved into water to produce calcareous water. Fresh gaseous carbon dioxide is supplied into the vessel 1 from the gaseous carbon dioxide source 3 by the amount of dissolved gaseous carbon dioxide by action of a regulator 4. In such a way, since gaseous carbon dioxide is replenished by the utilized amount, gaseous carbon dioxide is utilized without waste.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a carbonated water production device for producing soda water for drinking.

[Conventional technology]

A conventional carbonated water production apparatus is shown in FIG.

A conventional carbonated water production apparatus employs a method of directly blowing carbon dioxide gas from a carbon dioxide gas cylinder 3 into water 8 placed in a sealed container 1 to produce carbonated water. However, with this method, all of the carbon dioxide gas that is blown into the container does not dissolve into the water, so the carbon dioxide gas that cannot be dissolved escapes and accumulates in the gas area, such as the upper space of the container. That is, more carbon dioxide gas than is required to make water into carbonated water of a predetermined concentration is required.

[Problem to be solved by the invention]

In the conventional method described above, the carbon dioxide gas released into the gas portion without being completely dissolved cannot be used again to produce carbonated water, and the carbon dioxide gas cannot be used effectively.

The present invention was made in consideration of the quality of air quality, and provides a carbonated water production device that can economically use carbon dioxide gas.

[Means to solve the problem]

The first gist of the carbonated water production apparatus according to the present invention is that carbon dioxide gas at a constant pressure can be freely supplied to the gas section A in a sealable container 1, and water is pumped into the container 1 by a pump 5. The carbon dioxide gas in the gas part A is dissolved in the water by controlling the carbonated water level in two positions and introducing it as a jet by the water level detection mechanism 14 provided at two locations, upper and lower, inside the container 1. Carbonated water is taken out from the carbonated water intake port 9 via the valve 10 to the outside.

Second, the column of carbon dioxide gas bubbles induced in the carbonated water by the jet flows through the carbonated water intake port 9 provided at the bottom of the container 1.
This carbonated water production apparatus is characterized in that a gas-liquid separation plate 2 is provided above the carbonated water intake port 9 in the lower part of the container 1 to prevent the water from reaching the carbonated water.

The third device is a carbonated water production device characterized in that water level sensors for detecting the water level of carbonated water inside the container 1 are provided at two locations, upper and lower, and the water level is controlled at two positions.

In addition, if the height of the container 1 is high and the column of carbon dioxide bubbles induced by the small flow rate of the jet does not reach the carbonated water intake port 9 provided at the bottom of the container 1, then this As a carbon dioxide gas source that does not require the provision of the gas-liquid separation plate 2, a carbon dioxide gas cylinder may be used simply, but it is also possible to use other carbon dioxide gas generators.

Further, as a means for supplying a constant amount of carbon dioxide gas, a regulator or the like is used.

Further, as the valve 10, a check valve is used for boat fishing.

[For production]

With the above configuration, the carbon dioxide gas released into the gas section A in the container 1 without completely dissolving in the water is blown into the water again when water is introduced as a jet next time.

Therefore, the amount of carbon dioxide gas supplied to the carbon dioxide gas cylinder to carbonate the water is the same amount that is dissolved in the water.

In addition, by installing a gas-liquid separation plate and controlling the water level in two positions, undissolved carbon dioxide bubbles induced in the carbonated water by the jet flow can be mixed with the carbonated water from the carbonated water intake port provided at the bottom of the container. The amount of carbon dioxide gas required to make carbonated water is supplied from the carbon dioxide gas cylinder.

[Example] Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 shows an example of this. A nozzle 7 having only a small hole is provided in the upper part of the container 1, and a pump 5 is communicated with the nozzle 7 through a water outlet pipe 51 via a check valve 6.

The check valve 6 is oriented so as to stop the flow from the container 1 toward the pump 5, and the suction side of the pump 5 is communicated with a water source using a communication pipe (not shown).

Further, a carbonated water intake port 9 is provided at the bottom of the container 1, and a carbonated water intake port 13 and a solenoid valve 10 provided on the outside, and a squeezing device 1 are provided.
1 and a carbonated water outlet pipe 12 .

Further, the inside of the container 1 and the carbon dioxide source 3 are communicated with each other via a regulator 4 using a communication pipe 41.

Additionally, inside the container 1, there is an air vent 21 around the periphery as shown in FIG. A liquid separation plate 2 is provided above the carbonated water inlet 9. Here, the opening 21 of the gas-liquid separation plate 2 may have any shape as long as it allows the carbonated water to pass through smoothly.

In addition, if the height of the container 1 is high or the jet flow rate is small, so that the column of carbon dioxide gas bubbles induced by the jet does not reach the carbonated water intake port 9, the gas-liquid separation plate 2 may be omitted. I don't mind.

Further, inside this container 1, water level sensors 14 are provided at two locations, upper and lower, to detect the water level of carbonated water. The water level sensor 14 may be of any type, such as a float switch or electrode type, as long as it can detect the water surface. In addition, when using a capacitance type sensor or the like that can detect the water surface inside the container 1 from the outside as the water level sensor 14,
It may be provided outside the container 1.

With the above configuration, when the pump 5 is started and the solenoid valve 10 is opened at the same time, water is pumped up from the water source, and carbon dioxide gas at a constant pressure is blown into the container l as a jet from the carbon dioxide gas source 3, colliding with the water surface, and this At times, surrounding carbon dioxide gas is drawn into the water due to viscous force, etc. As a result, carbon dioxide gas is dissolved in water to produce carbonated water, and new carbon dioxide gas is supplied into the container 1 from the carbon dioxide gas source 3 by the action of the regulator 60 by the amount of dissolved carbon dioxide gas. This process is repeated continuously to produce carbonated water. At the same time, carbonated water and undissolved carbon dioxide gas are completely separated by the gas-liquid separation plate 2, and only the carbonated water exits from the carbonated water inlet 9 via the solenoid valve 10, the throttle device 11, and the carbonated water outlet 13. derived.

Here, since a constant pressure is applied within the container 1 by the regulator 4, the flow rate of water sent into the container 1 by the pump 5 and the flow rate of carbonated water led out to the outside usually do not match. For this purpose, the pump 5 or the T!
j, control the Mi valve 10 while turning it on and off.

〔Effect of the invention〕

In the carbonated water production device of the present invention, carbon dioxide gas is replenished in the amount that is used, so carbon dioxide gas can be used without wasting it.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing one embodiment of the present invention. FIG. 2 is a plan view of the gas-liquid separation plate, and FIG. 3 is a sectional view showing a conventional example. 1... Container, 2... Gas-liquid separation plate, 2100. Opening, 3... Carbon dioxide gas source, 4... Regulator 41
...Communication pipe, 5...Pump, 51...Outlet pipe, 6
... Check valve, 7... Nozzle, 8... Carbonated water, 9
... Carbonated water intake port, 10 ... Solenoid valve, 11 ... Squeezing device, 12-0. Carbonated water intake pipe, 13... Carbonated water outlet, A... Gas section, 14... Water level sensor Figure 1

Claims (3)

[Claims] (1) Carbon dioxide gas at a constant pressure can be freely supplied to the gas section in a sealable container, and by introducing water as a jet into the container using a pump, the carbon dioxide gas in the gas section is dissolved in the water, and at the same time, the carbon dioxide gas in the gas section is dissolved in the water. A carbonated water production device characterized in that carbonated water is taken out to the outside from a provided carbonated water intake port via a valve. (2) The carbonated water production apparatus according to item 1, wherein a gas-liquid separation plate is provided above the carbonated water intake port in the lower part of the container. (3) The carbonated water production device according to claim 1, wherein water level sensors are provided at two locations, upper and lower, to detect the water level of the carbonated water inside the container, and the water level is controlled at two positions.