JPS58164971A - Drier of cooling system - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a drying device for an absorption cooling system that utilizes the effect of an adsorbent such as zeolite absorbing refrigerants such as water and fluorocarbon gas. The purpose of this is to facilitate the removal and removal of refrigerant from the refrigerant to the refrigerant.

In recent years, absorption cooling cycles have been reconsidered as the simplest and most efficient method, or from the perspective of energy conservation, and one example is one that uses inorganic solid adsorbents such as zeolite and silica gel. .

A conventional absorption cooling system will be explained with reference to Figs. 3 and 4. 1 shows the entire cooling system, 2 shows a metal storage tank 4 simply filled with an adsorbent 3 such as zeolite, and the storage tank 4. This is a drying device in which a heater 5 such as a gas burner is installed at the bottom. 6 is a condenser that condenses the refrigerant, 7 is a refrigerant tank that stores the condensed liquid refrigerant, and 8 is an evaporator that evaporates the refrigerant, which are the main elements of the cooling system 1. Further, each element is connected and piped with steel pipes or the like. Further, a refrigerant condensation amount adjusting pulp 10 is provided at the outlet 9 of the storage tank 4, a refrigerant adsorption amount adjusting pulp 12 is provided at the inlet portion 11, and a refrigerant evaporation amount adjusting pulp 13 is provided at the outlet side of the refrigerant tank 7. The inside of this pipe is previously depressurized by evacuation or the like.

Next, the operating status of this cooling system 1 will be explained.

First, the condensation amount adjusting pulp 10 is opened, the adsorption amount adjusting pulp 12 and the evaporation amount adjusting pulp 13 are closed, and the storage tank 4 is heated by operating the heater 6. As a result, the adsorbent inside the storage tank 4 that has already adsorbed the refrigerant is heated, and the refrigerant is desorbed again. Next, this refrigerant is condensed in a condenser 6 to become a liquid refrigerant and stored in a refrigerant tank 7.

When a predetermined amount of liquid refrigerant has accumulated, the condensation amount adjusting pulp 1° is closed, the heating device 6 is turned off, and although not shown in the figure, a conventional cooling device such as air cooling or water cooling provided in the drying device 2 is activated. By cooling the storage tank 4, the adsorbent 3
to cool down. Next, the adsorption amount adjusting pulp 12 is opened, the evaporation amount adjusting valve 13 is adjusted according to the capacity of the evaporator 8, and the refrigerant is conveyed to the evaporator 8. The evaporator 8 is usually set in an indoor unit of an air conditioner, and is discharged into the room as cold air by a blower fan 14 or the like.

However, in the drying device 2 of the cooling system 1 shown above, since the absorbent 3 is simply stored in the metal storage tank 4, first, when the refrigerant is desorbed, Heat could only be transferred to the adsorbent 3 through the container wall of the storage tank 4. In addition, since the adsorbent 3 is an inorganic powder such as zeolite or silica gel, the thermal conductivity of the adsorbent 3 itself is extremely low compared to metal, so it acts as a heat insulator.
It is not easy to heat up to the adsorbent 3 located in the center of the storage tank 4, it is difficult to completely desorb the adsorbed refrigerant, and the heating takes a considerable amount of time. If you ignore this and increase the capacity of the heater 6, you will incur additional fuel costs such as gas, and the material constituting the storage tank 4 may deteriorate, and the heater 6 may
There was a problem that the adsorbent 3 in the storage tank 4 near the storage tank 4 was heated to an extremely high temperature, and the adsorbent 3 itself deteriorated.

In addition, when the refrigerant arrives, the inlet 1 of the storage tank 4
If the powdered adsorbent 3 is strongly aggregated due to the influence of the refrigerant such as water that has entered through the storage tank 1, the adsorption effect of the refrigerant on the adsorbent 3 will be extremely reduced. Only the adsorbent 3 close to 11 acts, and after the adsorption capacity reaches saturation, the refrigerant moves to the internal adsorbent 3, resulting in a diffusion phenomenon-like adsorption, which reduces the adsorption effect of the adsorbent 3. sometimes decreased. Similarly, when changing the refrigerant desorption operation to adsorption operation in the drying device 2, even if the storage tank 4 is cooled by air cooling, only the adsorbent 3 near the inner wall of the storage tank 4 is cooled, and the adsorption inside is cooled. The agent 3 may reach a high temperature state, and if refrigerant adsorption operation is performed in this state, the adsorbent 3 near the inner wall surface of the storage tank 4 will heat up.
However, there is a drawback that the adsorption effect of the refrigerant may occur, which in turn leads to a decrease in the cooling capacity.

The present invention solves the above-mentioned drawbacks of the conventional absorption cooling system by improving the drying device.

An embodiment of the present invention will be described below with reference to FIGS. 1 and 2. 1. An embodiment of the present invention is an improvement on the storage tank 4 of the drying device 26, 1, and 2 of the absorption cooling system 1 of the conventional example, and the system other than the storage tank 4 is based on the conventional example. do.

16 is a storage tank containing an adsorbent 16 such as zeolite made of metal such as copper or stainless steel, and has a large number of through pipes 17&, 17b... and a heat exchange plate 18a,
Consists of 18b... The plurality of through pipes 17a, 17
b... are made to penetrate inside the cylindrical storage tank 16 from the top surface to the bottom surface, and the penetration pipes 17a, 17b...
- are joined by welding etc. at the contact part of the side plane part,
A completely sealed storage tank 16 is obtained so that the adsorbent 16 does not come into contact with the outside air.

The inside of the storage tank 16 includes through pipes 17a, 17b...
- and a number of other holes 19a.

19b, 190, 19d...)
18a, 18b, . . . are arranged one above the other with appropriate intervals. The penetrating pipes 17a, 17b... pass through the heat exchange plates 18a, 18b... and come into contact with the heat exchange plates 18a, 18b, respectively. The parts are fixed by welding etc., and the adsorbent 16 is attached to the through pipes 17&, 17b...
and heat exchange plates) 18a, 18b, etc., and are filled in the storage tank 15. A heater 6 is provided at the bottom of the storage tank 15, which is one opening of the through pipes 17a, 17b, . . . .

The storage tank 16 thus produced is used in place of the storage tank 4 of the cooling system 1 shown in the conventional example.

In the cooling system 1 equipped with the drying device 2 having the storage tank 16 configured as described above, when the refrigerant is desorbed from the adsorbent 16, the heat of the heater 6 installed at the bottom of the storage tank 16 is , storage y l 15 (D'J-
m part ``''''''ba・, jjl'11''''・17b...
Heat exchange pre〒”':”,”),) 18 a,
18 b...,'.: Also conducts to the adsorbent 16 and is depleted. Therefore, the adsorbent 16 located anywhere within the storage tank 16 can be uniformly heated. Also, the through pipe 17a17b...
and heat exchange plates) 18a, 18b... are made of metal, so they have good heat conduction and can heat the adsorbent 16 to a predetermined temperature in a short time, saving energy required for heating. .

Further, when adsorbing the refrigerant from the adsorbent 16, first,
It is necessary to cool the adsorbent 16 such as zeolite to a temperature at which it can adsorb, but at this time too, although not shown in the figure, cooling heat such as air cooling or water cooling set in the drying device 2 is transferred to a storage tank. Not only from the wall surface of 16, but also from the through pipe 17a.
, 17b... and heat exchange plate) 18a, 18b...
... is also transmitted to the adsorbent 16. Therefore, the adsorbent 16 located anywhere can be cooled uniformly and in a short time, and the energy required for cooling can be saved.

Next, when adsorbing the refrigerant, the inlet part 1 of the storage tank 16
By adsorbing the refrigerant that enters from ``1'',
I, Adsorbent 1.6. , p, even if the adsorbent 16 aggregates, the entire adsorbent 16 is No strong aggregation occurs. Therefore, when the adsorbent 16 comes into contact with the refrigerant, there is no extreme decrease in area and no decrease in adsorption effect is observed.

As is clear from the above description, the drying device of the present invention is
A storage tank containing zeolite, etc. is provided with a large number of through tubes, and a metal heat exchange plate having multiple holes through which the through tubes are inserted is placed inside the storage tank at appropriate intervals to connect the through tubes. They are placed in close contact with each other, the space is filled with the adsorbent, and a heater is provided on one opening side of the through pipe of the storage tank, and has the following effects.

(b) During the desorption operation of refrigerant from the adsorbent, the heat from the heater installed in the storage tank can be transmitted not only through the storage tank wall but also through the through pipes and heat exchange plates. The adsorbent anywhere in the tank can be heated uniformly and in a short time, saving energy needed for heating.

(b) During the cooling operation of the adsorbent as a preparatory work for the adsorption operation of refrigerant from the adsorbent, the through pipes and heat exchange plates are used to prevent adsorption from occurring anywhere in the storage tank. Since the agent can also be cooled uniformly and in a short time, the energy required for cooling can be saved.

eC) Even if the adsorbent may aggregate due to refrigerant adsorption, the adsorbent is partitioned by a through pipe and a heat exchange plate, so the entire adsorbent will not aggregate firmly, and therefore the adsorbent will The contact area with the refrigerant does not decrease significantly, and no decrease in the adsorption effect is observed.

As described above, the present invention is highly useful as an adsorbent drying device for an absorption cooling system that utilizes the adsorption effect of zeolite, silica gel, etc.

[Brief explanation of the drawing]

Fig. 1 is a sectional view of the main parts of an adsorbent drying device showing an embodiment of the present invention, Fig. 2 is an enlarged sectional view of section A in Fig. 1, and Fig. 3 is a system diagram of a conventional absorption cooling system. , FIG. 4 is a sectional view of a main part of a conventional adsorbent drying apparatus. 16... Storage tank, 16... Adsorbent, 17a... Penetration pipe, 18a... Heat exchange plate. Figure 3 I Figure 1 Figure 2 Figure 4

Claims (1)

[Claims] A storage tank containing an adsorbent such as zeolite or silica gel, a heater such as a gas burner that heats the storage tank, and a condenser that condenses refrigerant such as fluorocarbon gas or water vapor desorbed by heating the adsorbent. , a refrigerant tank for storing the refrigerant after condensation, and an evaporator for evaporating the refrigerant; A through pipe that is divided into a plurality of parts by a heat exchange plate and that passes through the heat exchange plate and also through the storage tank is attached to the storage tank, and the heater is installed on the i-side opening side of the through pipe. Drying equipment for the cooling system in place.