JPS58110941A - Heat-accumulating water tank - Google Patents

Abstract

PURPOSE:To raise the heat accumulating efficiency of a heat-accumulating water tank, by causing movement of water by ejecting a pressure fluid to stagnation areas in the water tank. CONSTITUTION:A heat-accumulating water tank 20 is divided into a plurality of small rectangular heat-accumulating chambers 24A-24F by walls 22 having connecting pipes 26, and a furnace 28 is provided in each of the chambers 24A and 24F for heating and cooling heat-accumulating water 29. The discharge side of a pump 30 for drawing out the heat-accumulating water 29 from the chamber 29A is connected via a pipe 32 to descending pipes 34 respectively of the small heat-accumulating chambers 24A, 24B, 24C, 24E, 24F. Here, movement of water 29 is caused by ejecting the heat-accumulating water toward the chamber 24B in the chamber 24A, toward a corner portion in the chambers 24B, 24C and 24E, and toward the furnace 28 in the chamber 24F, respectively, by means of nozzles 36, 38, 40 and 42.

Description

[Detailed description of the invention] The present invention relates to a heat storage water tank that stores heat in water within the tank.

A heat storage water tank shown in FIG. 1 is used in air conditioners, freezers and refrigerators, dryers, etc. This heat storage water tank has a plurality of small heat storage chambers 10, and these small heat storage chambers 10 are communicated with each other through a communication pipe 12, and the heat storage water cooled and heated in the boiling tank 14 is transferred to these small heat storage chambers 10. It is designed to circulate through a communication pipe 12.

However, a stagnant portion is generated at the corner of the small heat storage chamber 10 and the stagnant water 16 remains without being circulated, resulting in a problem that the thermal efficiency is not improved.

In consideration of the above facts, the present invention aims to move stagnant water to obtain a heat storage water tank without a stagnant portion.

The heat storage water tank according to the present invention is configured to move stagnant water and eliminate stagnation by blowing out pressurized fluid from the pressure feeding part to the stagnation part through piping and a blowing nozzle.

Embodiments of the present invention will be described below with reference to the drawings.

As shown in FIG. 2, the heat storage water tank 20 according to this embodiment has six rectangular small heat storage chambers 24A to 24 divided by walls 22.
．． A communication pipe 26, which also serves as a ventilation pipe, is bored between adjacent small heat storage chambers to communicate between the adjacent small heat storage chambers.

A boiler 28 is provided in the small heat storage chambers 24A and 24F to cool and heat the heat storage water 29 in the small heat storage chamber.

A pump 30 serving as a pressure feeding section is installed adjacent to the small heat storage chamber 24F. This pump 3o sucks heat storage water from the small stomach heat chamber 24F and pumps it to the piping 32. The piping 32 is connected to the small heat storage chambers 24A, 2jB, 24C, 24
It is connected to down pipes 34 provided to E and 2'4F, respectively.

The small heat storage chamber 24A is connected to the down pipe 34 in the small heat storage chamber 24A.
A blowout nozzle 36 is provided along the wall surface of the chamber 2413 to blow out pressure water toward the small heat storage chamber 2413 and stir the stagnant water.

The down pipe 34 of the small heat storage chamber 24B is provided with a blowout nozzle 36 that blows out pressure water toward the corner of the small heat storage chamber 24B and moves water stagnant in the corner. Furthermore, a blow-off nozzle 40 is connected to the blow-off nozzle 3 in this down pipe 34.
The stagnant water moved by the blow-off nozzle 38, which is provided at a predetermined angle with respect to the blow-out direction, is smoothly moved to the adjacent small heat storage chamber 24C.

Similar to the small heat storage chamber 24B, the small heat storage chambers 24C and 24K are provided with blow-off nozzles 38, 40 to smoothly move the stagnant water at the corner of the small heat storage chamber to the downstream small heat storage chamber.

A falling pipe 34 is provided at a corner of the small heat storage chamber 24F, and a blowout nozzle 42 facing the direction of the boiler 28 is provided to move the stagnant water in the direction of the boiler 28.

As shown in FIG. 3, several of these blow-off nozzles 36 to 42 are provided vertically from near the surface of the heat storage water 29 to near the bottom when viewed from the horizontal direction.
It is designed to give an average jet flow to.

In this embodiment configured in this way, the heat storage water 29 cooled and heated by the boiler 28 sequentially moves and circulates within the small heat storage chambers.

Since stagnation tends to occur in the corners of the small heat storage chamber, if the pump 30 blows out the heat storage water from the small heat storage chamber 24F to each small heat storage chamber, the stagnant water in the corner of the small heat storage chamber will be removed by the pressure from the blow-off nozzle. Since it is stirred by water and smoothly moves to the small heat storage chamber downstream, it is possible to move the heat storage water without stagnation, improving heat storage efficiency. In this way, in this embodiment, since it is only necessary to attach the pump 30 and the piping 32 to 34', it can be easily attached to an existing heat storage water tank.

Although the above embodiment shows a configuration in which the heat storage water in the heat storage tank is pumped, the present invention is not limited to the above configuration, and it is also possible to send compressed air to the blow-off nozzle with a compressor.

As explained above, the heat storage water tank according to the present invention pumps the pressurized fluid from the pressure feeding part to the stagnation part in the water tank through the piping and the blowout nozzle, so the stagnant water is efficiently moved and the heat storage efficiency is improved. Compared to a heat storage tank, the equipment size can be made smaller, and the installation space and installation cost can be reduced.

[Brief explanation of drawings]

! Fig. 91S is a sectional view. 20... Heat storage water tank, 24A-24F... Small heat storage chamber, 29... Heat storage water, 3o... Pump, 32... Piping, 34... Falling pipe,
36, 38, 40.42...Blowout nozzle. 10 Figure 2 Figure 3

Claims (1)

[Scope of Claims] (1) A heat storage water tank characterized in that stagnant water is moved by providing piping and a blowout nozzle for blowing out pressurized fluid from a pressure feeding part to a stagnation part in the water tank. 12+ The heat storage water tank according to claim 1, wherein the pressure feeding section is a pump that pumps the heat storage water in the water tank to piping. (3) The heat storage water tank 0 according to claim 1, wherein the pressure-feeding unit is a compressor that sends compressed air to piping. (4) The blow-off nozzle is arranged toward a corner of the small heat storage chamber of the heat storage water tank. A heat storage water tank according to any one of claims 1 to 3.