JP3322316B2 - Adsorption type reactor module - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an adsorption type reactor module which constitutes an adsorption type refrigerator for generating cold water by utilizing the adsorption and desorption of a solid adsorbent such as zeolite, activated carbon and silica gel with a refrigerant. .

[0002]

2. Description of the Related Art A conventional adsorption-type reactor module in an adsorption-type refrigerator has a plurality of circular or polygonal fins provided on the outer periphery of each of heat transfer tubes made of copper or the like to form fin tubes. The space between the fins is filled with a solid adsorbent, and a wire mesh for preventing falling off is stretched outside the fins. In such a configuration, when used as an adsorption reactor of an adsorption refrigerator, the length and the number of fin tubes are set according to a desired refrigeration capacity, and these modules are arranged side by side in a vacuum vessel. It is composed. (See, for example, JP-A-62-91763)

[0003]

In such a module constituted by filling a solid adsorbent between the fins provided on the outer periphery of each of the plurality of heat transfer tubes, the heat transfer between the adsorbent and the heat transfer tubes is excellent. Although performed, the occupied area of the adsorbent relative to the area within the contours of these arranged modules when placed side by side in a vacuum vessel is small, and therefore the amount of effective adsorbent is small.

[0004] Therefore, in order to obtain the required refrigerating capacity, the number of modules to be installed in the vacuum vessel must be increased, which inevitably increases the area occupied by the module and the size of the vacuum vessel in which the module is installed. there were.

[0005]

In order to solve the above-mentioned problems, according to the present invention, a number of heat transfer tubes are integrally arranged side by side by a number of common fins, and a solid adsorbent is filled in a gap between the respective fins. The present invention proposes a box-shaped adsorption-type reactor module which is filled and covered with a gas-permeable covering material on the outside of the fin.

[0006]

In order to solve the above-mentioned problems, according to the present invention, a number of heat transfer tubes are integrally arranged side by side by a number of common fins, and a solid adsorbent is filled in a gap between the respective fins. We propose an adsorption-type reactor module that is filled and covered with a gas-permeable covering material on the outside of the fin.

Next, the present invention proposes to arrange a large number of heat transfer tubes in a staggered manner in the above-described configuration.

[0008] In the above structure, the air-permeable covering material is
It can be constituted by a perforated plate or a net.

According to the present invention, in the above construction, the value of the heat transfer area between the fins and the tube per unit weight of the adsorbent is in the range of 0.6 to 1.0 m ² / kg. Propose that.

Further, according to the present invention, in the above structure, the particle size of the adsorbent is set in a range of 40 to 12 mesh (0.35 to 1.5 mm), and from the center of the module to the surface of the adsorbent filled. It is proposed to limit the distance of up to 12mm.

The module of the present invention has a box-shaped configuration.
Therefore, by installing side by side the appropriate number in the vacuum chamber can be of an adsorbing reactor in accordance with the desired cooling capacity of the adsorption refrigerator. In such a module of the present invention, the solid adsorbent is filled between a large number of fins in which a large number of heat transfer tubes are integrally juxtaposed, that is, over the entire contour of the module. In comparison, the effective amount of the adsorbent for the occupied area of the module is large.

By arranging the heat transfer tubes in a staggered manner, the distance to each adsorbent can be averaged, and the heat transfer to all the adsorbents is made uniform, contributing to the uniformity of the temperature. I do.

On the other hand, for the adsorbent, the value of the heat transfer area between the fins and between the tubes per unit weight of the adsorbent is 0.6 to 0.6.
If the filling is performed within the range of 1.0 m ² / kg, the heat transfer becomes good, and the difference between the temperature of the heat medium flowing through the heat transfer tube and the temperature of the adsorbent can be reduced. The driving amount can be increased.

Further, by limiting the distance from the center of the module to the surface of the adsorbent to be filled to a maximum of 12 mm and setting the particle size of the adsorbent to a range of 40 to 12 mesh (0.35 to 1.5 mm). In addition, the mass transfer coefficient of the refrigerant can be increased, so that the cycle time of adsorption and desorption of the refrigerant by the adsorbent can be shortened, and the refrigeration capacity per unit time can be increased.

[0015]

Next, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 illustrates a main part of an embodiment of an adsorption type reactor module according to the present invention, and reference numeral 1 denotes a heat transfer tube. Many of the heat transfer tubes 1 are integrally juxtaposed by many common fins 2. The heat transfer tubes 1 and the fins 2 are each formed of a copper tube, an aluminum plate, or the like, as in the related art. In this embodiment, a number of heat transfer tubes 1 are arranged in a line at a constant pitch Tp.
In addition, many fins 2 are arranged side by side at a constant pitch Fp. Then, a space between the respective fins 2 is filled with a solid adsorbent 3 such as zeolite, activated carbon, and silica gel,
The outside of the fin 2 is covered with a gas-permeable covering material 4 to constitute a box-type module of an adsorption-type reactor. In Examples described later, the solid adsorbent 3 is crushed silica gel having a diameter of 0.5 mm. The air-permeable covering material 4 can be composed of a perforated plate such as a punched metal, a wire mesh, or the like. still,
The symbol L in the figure represents the distance from the center of the module to the surface of the solid adsorbent 3.

FIG. 2 shows an embodiment of a module having another configuration. In this configuration, a large number of heat transfer tubes 1 are arranged in a staggered manner. This module shows a configuration used in an experiment for confirming the effect of the present invention, and the experimental conditions are as follows. Experimental conditions: Hot water inlet 80 ° C Heat transfer area / adsorbent amount = 0.
87m ² / kg Cooling water inlet 26 ° C Fin pitch = 5mm Condenser 26 ° C Heat transfer area = 0.41m ² Evaporation temperature 12 ° C Adsorbent packed bed (one side,
L) = 12mm

An appropriate number of the box-shaped modules having the above configuration are arranged in a vacuum vessel (not shown), and a large number of heat transfer tubes 1 are connected in series and / or in parallel to allow a heat medium to flow. Thus, an adsorption-type reactor having a desired refrigeration capacity can be configured.

In the above configuration, in the regeneration step in the operation of the adsorption refrigerator, the regeneration of the adsorbent 3 is performed by flowing hot water or the like as a heat source as a heat source into the heat transfer tube 1 of the module. Do. That is, by flowing warm water into the heat transfer tube 1, the adsorbent 3 is heated via the heat transfer tube 1 and the fins 2 to desorb the refrigerant, and the refrigerant vapor thus desorbed from the adsorbent 3 is passed through the air-permeable covering material 4. And is condensed in a condenser constituting an adsorption refrigerator.

On the other hand, in the adsorption step, refrigerant is adsorbed by the adsorbent 3 by flowing cooling water or the like as a heat medium as a cooling source into the heat transfer tube 1. That is, by cooling the adsorbent 3 through the heat transfer tubes 1 and the fins 2, the refrigerant vapor supplied from the evaporator constituting the adsorption refrigerator to the vacuum vessel flows into the module through the air-permeable covering material 4. Then, it is continuously adsorbed by the adsorbent 3.

The operation of the adsorption refrigerator involving the operation of the adsorption reactor described above is the same as that of the conventional one, and will not be described.

Next, the results of the heat transfer analysis simulation of the adsorption type reactor module of the present invention using the one-dimensional model shown in FIG. 3 will be described. The heat transfer analysis was performed by analyzing the temperature distribution in the packed bed of the adsorbent 3 (15 points from the center position of the module to the surface position of the packed bed as described later) by the following method.

First, in the analysis, in the packed bed of the adsorbent,
It is assumed that heat exchange is performed under the following conditions. The sorbent particles are small enough. The reaction proceeds while the whole particles of the adsorbent always maintain a saturated state. The diffusion resistance of the refrigerant vapor is negligibly small. The refrigerant vapor pressure in the packed bed of the adsorbent is always constant. In addition, the adsorption and desorption reaction of the refrigerant by the adsorbent is defined as internal heat generation and heat conduction accompanied by heat absorption as macro.At the time of adsorption, the heat of adsorption is distributed to the temperature rise of the adsorbent and the heat dissipation by heat conduction. The heat transferred by the heat conduction and the heat corresponding to the temperature decrease of the adsorbent are used for the heat of desorption.

Under such conditions, the following series of equations is obtained.

(Equation 1) Next, the equation of the saturated vapor pressure of water (Antoine equation) is as follows.

(Equation 2)

On the other hand, when the data of the equilibrium adsorption amount of the adsorbent obtained by the static equilibrium adsorption amount measurement test is substituted into the DA equation and arranged, the following equation expressing the relationship between the water content m and PT is obtained. .

(Equation 3)

Further, by substituting the above equations (2) and (3) into the Crusius-Claperon equation, the following equation regarding the heat of adsorption H is obtained.

(Equation 4)

In the above equation, the pitch Fp of the fin 2
5 mm, the thickness of the fin 2 is 0.15 mm, the thickness of the adsorbent packed layer, that is, the distance L from the center of the module to the surface of the adsorbent being filled is 12 mm, and the cycle time of adsorption and desorption is 7 mm. The simulation was performed by the backward difference method with the temperature conditions of each part set as follows. Regeneration temperature Tg = 75 ° C. Adsorption temperature Ta = 30 ° C. Condensation temperature Tc = 30 ° C. Evaporation temperature Te = 10 ° C. In the above formula, each symbol is as shown below. Ca: Specific heat of adsorbent (silica gel) 0.22 (kcal / kg · K) m: Water content (kg / kg) Cw: Specific heat of condensed water 0.99 (kcal / kg · K) ρ: Specific weight of adsorbent 2200 (kg) / m ³ ) T: Absolute temperature (K) H: Heat of adsorption (kcal / kg ・ H ₂ O) λ: Effective thermal conductivity of adsorbent 0.25 (kcal / m ・ hr ・ ℃) Ps: Saturated vapor pressure of water vapor (MmHg) Tv: Steam temperature (K) Ta: Adsorbent temperature (K) Lo: Steam latent heat (kcal / kg) Tc: Cooling water, hot water temperature 303,353 (K) h: Heat transfer rate 186 (kcal / m ² hr: ° C) E: Adsorption characteristic energy 742.2 (cal / mol) R: Gas constant 1.192 (cal / mol · K) t: Time

FIGS. 4 and 5 show changes in the temperature distribution and the water content in the packed bed of the adsorbent 3 during the adsorption step obtained by the above simulation.
From the surface of the packed bed of the adsorbent 3 (mesh = 1) to the center of the module (L = 12 mm from the surface, mesh = 1)
This shows the position of each of the 15 points divided into 14 equal parts up to 5).

From this analysis result, in the module of the present invention, in the module of the present invention, the driving amount of the refrigerant is 100 cc / kg—the load of the adsorbent and the temperature difference ΔT = 5 ° C. between the adsorbent temperature and the heat medium inlet temperature are achieved in a cycle time of 7 minutes. The possibility that can be done was obtained.

Next, FIG. 6 shows the module of FIG.
The heat transfer area sandwiched between the heat transfer tube 1 and the fin 2
Shows the results of measuring the temperature of each part based on the above experimental conditions in order to confirm the heat conductivity with respect to the value per unit weight of the adsorbent. Under these experimental conditions, the temperature of the adsorbent at the time of adsorption and desorption is ΔT = It can be seen that it is within 5 ° C. The heat transfer area / adsorbent amount under these experimental conditions was 0.87 m ² as described above.
Therefore, in the module of the present invention, the value of the heat transfer area per unit weight of the adsorbent 3 is, for example, 0.6 to 1.0 m ² / kg which is a range including the above value. It can be seen that the heat transfer can be improved by setting the range.

FIG. 7 shows the result of actual measurement under some conditions together with the above-described theoretical calculation in order to confirm the ratio of the dynamic drive amount to the static drive amount.
As shown in the figure, when the particle diameter is 0.5φ, the dynamic driving amount becomes 90% or more with a cycle time of 7 minutes. 0.4mm ~
Using crushed silica gel distributed in the range of 0.9 mm (40 mesh to 20 mesh) under the following temperature conditions, the ratio of the dynamic drive amount to the static drive amount was 8
7.5%. Regeneration temperature Tg = 70 ° C. Condensation temperature Tc = 30 ° C. Adsorption temperature Ta = 34 ° C. Evaporation temperature Te = 10 ° C. From these facts, the particle size of the adsorbent 3 is 40 to 12 mesh (0.
It is understood that the mass transfer coefficient of the refrigerant can be increased by setting the range of 35 to 1.5 mm).

On the other hand, when the thickness of the packed layer of the adsorbent 3 is increased,
The effective heat transfer coefficient λ of the adsorbent 3 on the packed bed surface is reduced by the desorption of the steam, and the temperature becomes lower than the central part because it is used as the heat of desorption. Causes a decline. This can lead to an increase in the residual moisture content of the adsorbent on the packed bed surface, and hence a decrease in the amount of refrigerant drive, and an increase in the resistance of the refrigerant flow passage through the voids of the adsorbent in the packed bed, so that it cannot be too large. Instead, it is preferable to limit the distance L under the experimental conditions described above, that is, the distance from the center of the module to the surface of the adsorbent 3 that is being filled, to a maximum of 12 mm.

[0033]

As described above, the present invention has the following effects. The amount of the adsorbent effective for the area occupied by the module is large, and the size and performance of the adsorption reactor can be reduced. Since the module has a box structure ,
A desired number of units can be easily installed in a vacuum vessel, and an adsorption-type reactor corresponding to a desired refrigeration capacity of the adsorption-type refrigerator can be configured. By optimizing the heat transfer area, heat transfer can be promoted, and the refrigerant drive amount per unit weight can be increased. The cycle time can be reduced by increasing the mass transfer coefficient of the refrigerant by optimizing the particle size of the adsorbent and the thickness of the packed bed.

[Brief description of the drawings]

FIG. 1 is an explanatory perspective view showing a main part of a configuration of an embodiment of an adsorption type reactor module of the present invention.

FIG. 2 is an explanatory perspective view showing a main part of the configuration of another embodiment of the adsorption type reactor module of the present invention.

FIG. 3 is a one-dimensional model in a heat transfer analysis of the adsorption-type reactor module of the present invention.

FIG. 4 is an explanatory diagram showing the results of heat transfer analysis of the adsorption-type reactor module of the present invention as a temperature distribution in a packed bed of an adsorbent.

FIG. 5 is an explanatory diagram showing a result of a heat transfer analysis of the adsorption-type reactor module of the present invention as a change in a water content in a packed bed of an adsorbent.

FIG. 6 shows the results of temperature measurement of each part in the module of FIG. 2;

FIG. 7 shows theoretical analysis and experimental results for confirming a ratio of a dynamic driving amount to a static driving amount.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Heat transfer tube 2 Fin 3 Adsorbent 4 Air-permeable covering material

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Masao Ogura 2-8-105, Wakaba-cho, Tachikawa-shi, Tokyo (72) Inventor Hideaki Terasawa 478, Bonsai-cho, Omiya-shi, Saitama (56) References (JP, A) Japanese Patent Application Laid-Open No. Sho 62-216633 (JP, A) International Publication No. 90/10491 (WO, A1) Proceedings of the Japanese Refrigeration Association Scientific Lecture, 1991, Japan Refrigeration Association, November 1991 7th, p. 101-104 (58) Field surveyed (Int. Cl. ⁷ , DB name) F25B 17/08 F25B 35/04

Claims (7)

(57) [Claims] 1. A box in which a number of heat transfer tubes are integrally juxtaposed by a number of common fins, a gap between the respective fins is filled with a solid adsorbent, and the outside of the fins is covered with a gas-permeable covering material . Adsorption type reactor module characterized by being configured in a mold 2. The adsorption reactor module according to claim 1, wherein the plurality of heat transfer tubes are arranged in a staggered manner. 3. The adsorption-type reactor module according to claim 1, wherein the gas-permeable covering material is constituted by a perforated plate. 4. The module according to claim 1, wherein the air-permeable covering material is constituted by a net. 5. The adsorbent according to claim 1, wherein the value of the heat transfer area between the fins and the tube per unit weight of the adsorbent is in the range of 0.6 to 1.0 m2 / kg. Adsorption reactor module characterized by filling 6. The adsorption reactor module according to claim 1, wherein the particle size of the adsorbent is in a range of 40 to 12 mesh (0.35 to 1.5 mm). 7. A module according to claim 1, wherein the distance from the center of the module to the surface of the adsorbent is limited to a maximum of 12 mm.