JP4821563B2 - Adsorption module and method of manufacturing adsorption module - Google Patents

Description

  The present invention relates to an adsorption module and a production method of the adsorption module, and is suitable for application to an adsorber that evaporates the refrigerant by using, for example, the action of the adsorbent adsorbing the gas-phase refrigerant and exhibits the refrigerating capacity by the latent heat of vaporization. Is.

  Conventionally, this type of adsorber has an adsorption heat exchanger filled with an adsorbent and a heat exchanger in which an adsorbed medium adsorbed / desorbed evaporates / condenses. Some of them are accommodated in a vacuum vessel constituting the outer frame of the vessel (see Patent Document 1).

  In the technique disclosed in Patent Literature 1, a copper powder or the like sintered in an adsorption heat exchanger is used as a heat transfer promoting material. In this technique, the copper powder and the adsorbent are mixed and sintered, and the heat transfer tube through which the heat exchange medium flows is integrally encapsulated.

  In addition, the adsorption heat exchanger constituting the adsorber and the above heat exchanger are individually manufactured, and then the adsorption heat exchanger and the heat exchanger manufactured individually are accommodated in the vacuum vessel, and the air is airtight. It is assembled.

In the technique disclosed in Patent Document 2, a serpentine heat exchanger is accommodated in a vacuum vessel, and a metal fabric and an adsorbent woven with metal fibers are placed around the serpentine heat exchanger in the vessel.
JP-A-4-148194 JP 2002-31426 A

  However, in the prior art according to Patent Document 1, an adsorption heat exchanger filled with an adsorbent and a vacuum container containing the adsorbent are separately manufactured, and then assembled and integrated. Therefore, there is a problem that many manufacturing steps are required.

  Moreover, in the prior art by the said patent document 2, since this metal fabric is only contacting the serpentine type heat exchanger and not joining metallically, it puts a metal fabric substantially in the circumference | surroundings of a serpentine type heat exchanger. The heat transfer improvement effect by this is not high, and the adsorption / desorption rate of the adsorbent cannot be improved.

  The present invention has been made in consideration of such circumstances, and an object of the present invention is to achieve an adsorption module and an adsorption module that are efficient by reducing the manufacturing process, have excellent heat transfer characteristics, and suppress energy loss. It is in providing the manufacturing method of.

  In order to achieve the above object, the present invention employs the following technical means.

That is, in the invention described in claims 1 to 8, the heat medium pipe (21) has a plurality of heat medium pipes (21) through which the heat exchange medium flows in the housing (3) capable of holding the inside in a vacuum. An adsorption module (1) in which a porous heat transfer body (23) having pores (23a) and an adsorbent (24) filled in the pores (23a) are provided in a peripheral portion (22). The porous heat transfer body (23) is metal-bonded to each other by sintering by mixing and heating any powder, particulate, or fibrous metal powder with the adsorbent (24). In addition, the adsorbent (24) is filled in the pores (23a) formed by metal bonding between the metal powders, and the metal powder is bonded to the heat medium pipe (21) made of the same first metal as the metal powder. The case (3) is a second metal whose melting temperature is higher than the sintering temperature of the metal powder. Is formed, characterized in that the porous heat transfer member (23) and the housing (3) is insulated by not being metallically bonded.

  According to this, the porous heat transfer body (23), the heat medium pipe (21), and the housing (3) that accommodates the porous heat transfer body (23) and the heat medium pipe (21) inside, respectively, Since the metal powder is sintered as a sintered body, the same metal material as the metal powder, and the second metal having a melting temperature higher than the sintering temperature of the metal powder, the porous heat transfer body (23 ) And the heat medium pipe (21) can be metallically bonded by sintering the metal powder, and the casing (3) having a melting temperature higher than the sintering temperature of the metal powder, and the porous heat transfer body (23) Is not metallicly connected to the porous heat transfer body (23) and the housing (3), and a heat insulating state is obtained.

  Moreover, with such a configuration, a manufacturing process for integrating the porous heat transfer body (23), the heat medium pipe (21), and the housing (3) can be performed, for example, in the housing (3). The medium pipe (21) is arranged, and the peripheral part (22) of the heat medium pipe (21) is filled with metal powder to be sintered as a sintered body, and then placed in a furnace and heated at the sintering temperature. It can be done with a simple process.

  Therefore, it is possible to provide an adsorption module (1) that can be made efficient by reducing the number of manufacturing steps and that has excellent heat transfer characteristics and suppresses energy loss.

  In particular, the housing (3) is configured so that the internal housing space is partitioned by a plurality of members brazed to each other by a brazing material, as in the invention described in claim 2, and the porous heat transfer body The metal powder (23) is preferably configured so that the sintering temperature is the same as the brazing temperature of the brazing material.

  By comprising in this way, in the said manufacturing process, the process of sintering metal powder to the peripheral part (22) of a heat-medium pipe | tube (21), the process which makes an adsorbent (24) the state which can exhibit an adsorption effect, The step of brazing and joining the parts constituting the adsorption module (1) can be performed by the step of brazing. Therefore, it is possible to provide an adsorption module (1) that can achieve excellent productivity by reducing the number of manufacturing steps and improving efficiency.

  The first metal of the heat medium pipe (21) and the second metal of the housing (3) are copper or copper metal, and the second metal is the second metal of the housing (3). Stainless steel or iron is preferably used, and a gap (δ) is preferably provided between the porous heat transfer body (23) and the wall surface in the housing (3).

  According to this, in the heat insulation state between the porous heat transfer body (23) and the housing (3), the heat insulation is improved by the formation of a gap (δ) therebetween.

  Further, the porous heat transfer body (23) has a technical means called an adsorption module (1) having a shape formed by the wall surface in the housing (3) as in the invention described in claim 4. Can be adopted.

  Moreover, as for the housing | casing (3) like the invention of Claim 5, it is preferable that a housing | casing (3) is cylindrical shape. Thereby, since the pressure resistance is improved and the casing (3) can be thinned, it is possible to reduce the cost of the adsorption module (1) that has excellent heat transfer characteristics and suppresses energy loss.

  Further, it is preferable that an adsorbed medium passage (25) through which the adsorbed medium flows is provided between the heat medium pipes (21) as in the inventions of claims 6 to 7.

  In the case where the porous heat transfer body (23) and the adsorbent (24) are provided in the periphery of the heat medium pipe (21), the porous heat transfer body (23) is a so-called heat transfer using metal powder as a sintered body. By using the fin, the contact area with the adsorbent (24) filled in the heat transfer fin is increased, and the heat transfer characteristics are improved. However, depending on the thickness of the peripheral portion of the heat medium pipe (21) in the porous heat transfer body (23), the diffusion resistance of the adsorbed medium when the adsorbent (24) adsorbs / desorbs the adsorbed medium. The adsorption / desorption rate of the adsorbent (24) does not increase as intended, and as a result, the cooling performance may not be improved.

  On the other hand, in the inventions according to claims 6 to 7, since the adsorbed medium passage (25) through which the adsorbed medium flows is provided between the heat medium pipes (21), the porous heat transfer body (23 ) It becomes easy to permeate the adsorbed medium into the adsorbent (24) inside, and the diffusion resistance of the adsorbed medium can be reduced.

  In particular, in the invention according to claim 7, the distance from the inner peripheral surface of the adsorbed medium passage (25) to the outer peripheral surface of the adjacent heat medium pipe (21) is set so that the adsorbed medium is the heat medium pipe (21). The penetration depth (r2) penetrating toward the heat transfer pipe (21), so that the penetration depth (r2) is substantially equal to the heat transfer distance (r1) from the heat transfer pipe (21). The adsorbed medium passageway (25) is arranged in the front.

  According to this, the adsorbed medium passage (25) is placed between the heat medium pipes (21) so that the penetration depth (r2) related to the adsorption and desorption rates is substantially equal to the heat transfer distance (r1). Since it is disposed, it is possible to provide a high-performance adsorption module (1) having excellent heat transfer characteristics and low diffusion resistance of the medium to be adsorbed.

  Moreover, in invention of Claim 8, in the adsorption | suction module (1) as described in any one of Claim 1-7, a housing | casing (3) encloses the said to-be-adsorbed medium inside, An external evaporator and a condenser are coupled to the adsorbed medium so as to be able to circulate. The adsorbed medium flows from the evaporator side during adsorption, and the adsorbed medium flows to the condenser side during desorption. It is characterized by flowing out.

  According to this, since the adsorbed medium is guided to the separately provided evaporator and condenser at the time of adsorption and desorption, the evaporator and the condenser are wasted at the time of desorption and adsorption. Does not produce energy.

In the inventions according to claims 9 to 13 , the heat medium pipe (21) through which the heat exchange medium flows, and the powder form, which is sintered and bonded as a porous heat transfer body (23) to the heat medium pipe (21), Adsorbent (24) present in the peripheral portion (22) of the heat medium pipe (21) made of the same metal as the metal powder and the metal powder made of copper or copper metal, either in the form of particles or fibers. ) In the housing module (3) formed of the second metal made of stainless steel or iron, the heat medium pipe (21) is disposed inside the housing (3) and assembled. Assembling step, metal powder and adsorbent (24) are mixed and put in the housing (3), and the metal powder and adsorbent (24) are put on the peripheral part (22) of the heat medium pipe (21). The filling step to be positioned and the filling port containing the metal powder and the adsorbent (24) in the filling step is closed Metal Te, and before brazing housing forming step of forming a brazing front of the housing, by heating put before brazing of the housing in the furnace, the metal powder is sintered, the metal powders with each other Bonding to form a porous heat transfer body (23), metal bonding the porous heat transfer body (23) to the heat medium pipe (21), and the heat medium pipe (21) and the casing (3) And a brazing step for joining.

  According to this, the process which sinters metal powder to the peripheral part (22) of a heat-medium pipe | tube (21), the process which makes an adsorbent (24) the state which can exhibit an adsorption effect, and an adsorption module (1) are comprised. Since the process of brazing and joining parts is performed by the brazing process, an efficient manufacturing method with a reduced number of manufacturing processes can be provided. Therefore, it is possible to provide a method for manufacturing an adsorption module that is excellent in heat transfer characteristics, suppresses energy loss, and reduces the number of manufacturing steps and is efficient.

In the above-described method for manufacturing an adsorption module, in the case of an adsorption module further comprising an adsorbed medium passage (25) disposed between the heat medium pipes (21) as described in claim 10 or 11 , a filling step Puts the metal powder and the adsorbent (24) in the housing (3), positions the metal powder and the adsorbent (24) in the peripheral portion (22) of the heat medium pipe (21), and The adsorbed medium passage (25) is preferably located between the heat medium pipes (21).

  According to this, the step of positioning the metal powder and the adsorbent (24) in the peripheral part (22) of the heat medium pipe (21) in the housing (3), and the medium to be adsorbed between the heat medium pipe (21) Since the step of positioning the passage (25) is performed by the filling step, excellent productivity can be improved.

In particular, as in the eleventh aspect of the present invention, in the filling step, it is preferable to arrange a jig for providing the adsorbed medium passageway (25) between the heat medium pipes (21).

  According to this, the space of the adsorbed medium passage (25) is ensured only by inserting a jig into the metal powder and adsorbent (24) mixed in the peripheral part (22) of the heat medium pipe (21). can do.

In the invention described in claim 12 , the melting temperature of the brazing material used for brazing and joining in the brazing step is in the range of 700 to 1000 ° C.

  According to this, since the range of 700 to 1000 ° C. is the temperature at which the copper powder as the metal powder is sintered, the brazing and bonding are performed by passing the housing (3) before brazing once through the furnace. The ligation can be performed simultaneously.

  In addition, the code | symbol in the bracket | parenthesis of each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

(First embodiment)
The adsorption module according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is an external view showing the adsorption module of this embodiment. FIG. 2 is a cross-sectional view taken along line II in FIG. FIG. 3 is a longitudinal sectional view taken along line III in FIG. 4 is a schematic cross-sectional view showing the adsorbent packed bed in FIG. FIG. 5 is a flowchart showing the manufacturing process for an example of the manufacturing method of the adsorption module of the present embodiment.

  The adsorption module 1 shown in FIG. 1 is an adsorption type utilizing the fact that the adsorbent contained therein evaporates the refrigerant using the action of adsorbing the gas-phase refrigerant (water vapor) and exhibits the refrigerating capacity by the latent heat of vaporization. It is used for a refrigerator and can also be applied to an air conditioner for vehicles. As shown in FIGS. 2 and 3, the adsorption module 1 includes an adsorption heat exchanger 2 in a casing 3 constituting a housing. The adsorption heat exchanger 2 includes a heat medium pipe 21 through which a heat exchange medium (refrigerant) flows, and a porous heat transfer body 23 having pores 23a and an adsorbent in a peripheral portion 22 of the heat medium pipe 21. 24 is provided.

  Specifically, as shown in FIGS. 2 and 4, the adsorption heat exchanger 2 includes a porous heat transfer body 23 having pores 23a and the same metal as the porous heat transfer body 23 (hereinafter referred to as a first metal). ) A heat medium pipe 21 made of a system material and an adsorbent 24 filled in the pores 23a.

  The porous heat transfer body 23 is a sintered body that is obtained by heating and melting a metal powder having excellent thermal conductivity without being melted. As the metal powder, copper or a copper alloy (copper in this embodiment) is used. For example, the copper powder is formed in one of powder, particles, and fibers (in this embodiment, fibers). If it is what is done. The heat medium pipe 21 made of the same first metal as the copper powder of the porous heat transfer body 23 is made of copper or a copper alloy (copper in this embodiment).

  Such a porous heat transfer body 23, that is, a sintered body in which copper powder is sintered and bonded, has fine sintered fins (hereinafter referred to as porous sintered fins) having pores 23a as shown in FIG. Form. The pores 23a are fine pores that match the adsorbent 24 having a fine particle diameter compared to copper powder so as to be filled. Further, the porous heat transfer body 23 is sinter-bonded to the peripheral portion 22 of the heat medium pipe 21 made of copper by the sinter bond of copper powder.

  As shown in FIG. 3, the porous heat transfer body 23 is formed in the peripheral portion 22 of the plurality of cylindrical heat medium pipes 21 so that the whole extends in one direction. Further, as shown in FIG. 2, the porous heat transfer body 23 is formed in a shape along the inner peripheral wall of the housing 3 that accommodates the porous heat transfer body 23 therein, and has a cylindrical shape as a whole. is there.

  The adsorbent 24 is formed into a large number of fine particles, and is made of, for example, silica gel, zeolite, activated carbon, activated alumina, or the like. The adsorbent 24 is filled in the pores 23 a of the porous heat transfer body 23.

  Here, the porous heat transfer body 23 in the peripheral portion 22 of the heat medium pipe 21 is referred to as an adsorbent packed layer. This adsorbent packed layer corresponds to the thickness L (see FIG. 4) of the porous sintered fin that is sintered and bonded at the peripheral portion 22 of the heat medium tube 21.

  Next, the adsorption module 1 provided with the adsorption heat exchanger 2 integrally formed in the housing 3 will be described with reference to FIGS.

  The adsorption module 1 includes an adsorption heat exchanger 2, and a casing 3 having a casing body 31, sheets 32 and 33, and tanks 34 and 35. A housing | casing consists of 2nd metals, such as stainless steel or iron whose melting temperature is higher than the sintering temperature of copper powder. Stainless steel or iron has a relatively low thermal conductivity. In this embodiment, the second metal of the housing is stainless steel.

  The housing body 31 is formed in a cylindrical shape, and is formed so that the porous heat transfer body 23 of the substantially cylindrical adsorption heat exchanger 2 can be accommodated therein. Moreover, the upper end side opening part and the lower end side opening part of the housing body 31 are formed so as to be capable of being sealed with sheets 32 and 33. An adsorbed medium inflow pipe 36 and an adsorbed medium outflow pipe 37 capable of guiding water vapor to the adsorbent packed bed of the adsorption heat exchanger 2 are provided on the upper portion of the housing body 31.

  By sealing the casing body 31 and the sheets 32 and 33 in this way, the inside can be maintained in a vacuum. As a result, in the internal sealed space formed by the casing body 31 and the sheets 32 and 33, there is no other gas (gas phase refrigerant) other than water vapor as the adsorbed medium.

  At the time of adsorption, the water vapor is distributed from the evaporator side to the adsorbed medium passage 25 through the adsorbed medium inflow pipe 36. The water vapor distributed to the adsorbed medium passage 25 penetrates into the adsorbent packed bed. Further, at the time of desorption, the water vapor is discharged from the adsorbent packed bed, and the discharged water vapor is guided to the condenser side from the adsorbed medium outflow pipe 37 through each adsorbed medium passage 25.

  The sheets 32 and 33 are formed with through holes 32a and 33a through which the heat medium pipe 21 can pass. The through holes 32a and 33a and the heat medium pipe 21 are airtightly fixed by joining by brazing or the like.

  The tanks 34 and 35 are provided with a heat medium inflow pipe 38 and a heat medium outflow pipe 39 capable of guiding the heat exchange medium. The heat exchange medium flows into the heat medium inflow pipe 38 of the lower tank 34, flows out of the heat medium outflow pipe 39 of the upper tank 35 through the heat medium pipe 21.

  The lower tank 34 and the upper tank 35 are tanks for supplying and distributing the heat exchange medium to the plurality of heat medium tubes 21.

  Note that the casing 3 and the heat medium pipe 21 may have any of a cylindrical shape, an elliptical shape, and a rectangular shape in the radial cross section.

  Next, the manufacturing process of the adsorption module 1 will be described with reference to FIG. The manufacturing process of the adsorption module 1 includes a metal powder (copper powder) formed as a sintered body in the housing 3 and an assembly process (step S100) for assembling each component before the process of filling the adsorbent. The filling step (step S200) for filling the case 3 with the copper powder and the adsorbent 24, and the case formation for closing the filling port filled with the copper powder and the adsorbent 24 to form the case 3 before brazing. A process (step S300) and a brazing process (step S400) for brazing the casing 3 before brazing into a furnace are provided.

  The assembly process of step S100 is a preparation process of the filling process of the copper powder and the adsorbent 24 in step S200, and the components that can be assembled before filling the copper powder and the adsorbent 24 are assembled as much as possible. It is preferable to keep it.

  In the assembly process of step S100, in order to hold and fix the heat medium pipe 21 which is a component of the adsorption heat exchanger 2 in the housing 3, first, one end of the plurality of heat medium pipes 21 is attached to the sheet 32. The sheet 32 and the heat medium pipe 21 are fixed by expanding (or expanding) the heat medium pipe 21 inserted into the through hole 32a. Next, the sheet 32 is assembled and fixed to the opening on the lower end side of the housing body 31. In this state, the upper end side opening of the housing body 31 is opened, and the heat medium pipe 21 is held and fixed in the housing body 31.

  In the casing main body 31, adjacent heat medium tubes 21 are provided at predetermined intervals, and the heat medium tube 21 has a peripheral portion 22 which is a space.

  Next, in the filling step of Step S200, the casing main body 31 is filled with the copper powder to be sintered on the peripheral portion 22 of the heat medium pipe 21 and the adsorbent 24 to be held. First, in the process of step S200, the copper powder is removed from the upper end side opening where the sheet 33 of the housing body 31 is not assembled, or from the communication hole connected to the adsorbed medium inflow pipe 36 and the adsorbed medium outflow pipe 37. The adsorbent 24 is mixed. As shown in FIGS. 2 and 3, a predetermined amount of the mixture of the copper powder and the adsorbent 24 is filled in the peripheral portion 22 of the heat medium pipe 21.

  Next, after a predetermined amount of the mixture of the copper powder and the adsorbent 24 is filled, a predetermined pressing force is applied from above in FIG. 3 using a pressurizing jig or the like to solidify the mixture of the copper powder and the adsorbent 24.

  Next, in the case forming process in step S300, all components that require brazing (joining) are assembled before the brazing process in S400. First, the sheet 33 is assembled and fixed in the upper end side opening of the housing body 31. In addition, the communication hole of the housing body 31 and the adsorbed medium inflow pipe 36 and the adsorbed medium outflow pipe 37 are assembled and fixed.

  Next, the lower tank 34 and the upper tank 35 are assembled and fixed to the sheets 32 and 33 or the housing body 31. Further, the heat medium inflow pipe 38 and the heat medium outflow pipe 39 are assembled and fixed to the lower tank 34 and the upper tank 35.

  Next, in the brazing process of step S400, the parts constituting the adsorption module 1 are brazed (joined), the copper powder filled in step 200 is sintered, and the sintered body of the copper powder and heat This is a step of performing sintering bonding (bonding) with the medium tube 21 and fixing the adsorbent 24 inside the sintered body (porous heat transfer body).

  First, it is placed on a component that requires brazing (joining). At least a joint part between the sheets 32 and 33 and the heat medium pipe 21 that is assembled and fixed through the sheets 32 and 33, a joint part between the sheets 32 and 33 and the housing body 31, and the sheet 32, Let's put it at the joint part of 33 and tanks 34 and 35.

  A copper material obtained by grading a brazing material may be used for the sheets 32 and 33 and the tanks 34 and 35. Thereby, the effort which is going to put on the said junction part can be saved.

  Moreover, since the sintering temperature of copper powder is in the range of 700 ° C to 1000 ° C, the brazing material having a melting temperature included in the range of 700 ° C to 1000 ° C is used. For example, the brazing material uses a copper-based or silver-based material. Further, since the adsorbent 24 is exposed to the high temperature atmosphere in the furnace, a material that is not destroyed at the furnace temperature (700 ° C. or higher) is used.

  Since the volume of the copper powder is reduced by sintering, as shown in FIG. 3, there is a gap δ between the porous heat transfer body 23 formed by sintering the copper powder and the inner peripheral wall of the housing 3. Arise. Further, the porous heat transfer body 23 has a shape formed by the inner peripheral wall of the housing 3.

  In the present embodiment described above, the porous heat transfer body 23, the heat medium pipe 21, and the casing 3 housing the porous heat transfer body 23 and the heat medium pipe 21 therein are sintered as sintered bodies, respectively. The copper powder as the metal powder, the same metal material as the metal powder, and the stainless steel as the second metal whose melting temperature is higher than the sintering temperature of the metal powder. As a result, the porous heat transfer body 23 and the heat medium tube 21 can be metallically bonded by sintering the metal powder, and the casing 3 having a melting temperature higher than the sintering temperature of the metal powder, and the porous heat transfer Since the body 23 is not metallicly bonded, the heat transfer body 23 and the housing 3 are insulative.

  In addition, the manufacturing process for integrating the porous heat transfer body 23, the heat medium pipe 21, and the housing 3 by arranging the heat medium pipe 21 in the housing 3, for example, After filling the peripheral portion 22 of the heat medium tube 21 with copper powder to be sintered as a sintered body, it can be performed by a simple process in which it is placed in a furnace and heated at the sintering temperature.

  Therefore, it is possible to provide an adsorption module 1 that can be made efficient by reducing the manufacturing process and that has excellent heat transfer characteristics and suppresses energy loss.

  Moreover, the housing | casing 3 is comprised so that an internal accommodation space may be divided by the some member brazed mutually by the brazing material like a present Example, The copper powder of the porous heat exchanger 23 is the following. It is preferable that the sintering temperature is the same as the brazing temperature of the brazing material.

  By comprising in this way, in the said manufacturing process, the process which sinters copper powder to the peripheral part 22 of the heat-medium pipe | tube 21, the process which makes the adsorbent 24 the state which can exhibit an adsorption effect, and the adsorption module 1 are comprised. The step of brazing and joining the parts to be performed can be performed by the step of brazing. Therefore, it is possible to provide the adsorption module 1 that can achieve excellent productivity by reducing the number of manufacturing steps and improving efficiency.

  In particular, the first metal of the heat medium pipe 21 and the second metal of the housing 3 are made of copper as the first metal and stainless as the second metal as in this embodiment, It is preferable to have a gap δ between the inner peripheral wall surface of the housing 3. Thereby, the heat insulation state improves between the heat insulation state between the porous heat transfer body 23 and the housing | casing 3, when the clearance gap (delta) arises in the meantime.

  By doing so, it is possible to reduce the loss of energy that is dissipated by the heat energy applied to the adsorption heat exchanger 2 being transmitted to the housing surface. Moreover, the loss of heat energy can be suppressed by using stainless steel with a relatively low thermal conductivity for the housing 3.

  Further, by using the stainless steel or iron casing 3 as described above, the mechanical strength of the casing 3 can be improved and the thickness of the casing 3 can be reduced.

  In particular, the housing 3 is preferably cylindrical as in this embodiment. Thereby, since the pressure resistance is improved and the casing 3 can be thinned, it is possible to reduce the cost of the adsorption module 1 that has excellent heat transfer characteristics and suppresses energy loss.

  Further, in the present embodiment described above, the housing 3 in the adsorption module 1 is configured to enclose the adsorbed medium inside and to couple the external evaporator and condenser to the adsorbed medium in a flowable manner. The adsorbed medium flows from the evaporator side during adsorption, and the adsorbed medium flows out to the condenser side during desorption. According to this, since the adsorbed medium is guided to the separately provided evaporator and condenser at the time of adsorption and desorption, the evaporator and the condenser are wasted at the time of desorption and adsorption. Does not produce energy.

  Moreover, in this embodiment demonstrated above, in the manufacturing method of the adsorption module 1, the assembly which assembles | assembles each component before the process of filling the copper powder formed as a sintered compact in the housing | casing 3, and the adsorption agent 24 is carried out. Attaching step, filling step of filling the case 3 with the copper powder and the adsorbent 24, and case forming step of closing the filling port filled with the copper powder and the adsorbent 24 to form the case 3 before brazing. And a brazing step of brazing the casing 3 before brazing into a furnace.

  Thus, a step of sintering copper powder on the peripheral portion 22 of the heat medium pipe 21, a step of allowing the adsorbent 24 to exert an adsorbing action, and a step of brazing and joining the components constituting the adsorption module 1 together. Since it is carried out by the brazing process, an efficient manufacturing method with a reduced number of manufacturing processes can be provided.

  In the embodiment described above, the melting temperature of the brazing material used for brazing and joining in the brazing step is preferably in the range of 700 to 1000 ° C. According to this, since the range of 700 to 1000 ° C. is the temperature at which the copper powder is sintered, the brazing and sintering are simultaneously performed by passing the casing 3 before brazing once through the furnace. Can do.

(Second Embodiment)
A second embodiment of the present invention is shown in FIG. The second embodiment is applied to the adsorption module 1 having the adsorbent 24 that is not heat resistant to the sintering temperature. FIG. 6 is a cross-sectional view showing the adsorption module of the present embodiment. FIG. 7 is a diagram for explaining a manufacturing process related to the manufacturing method of the adsorption module of the present embodiment, and is a schematic cross-sectional view seen from VII in FIG. FIG. 8 is a flowchart showing a manufacturing process for an example of the manufacturing method of the adsorption module of the present embodiment.

  In this embodiment, as shown in FIGS. 6 and 7, the configuration itself of the adsorption module 1 is the same, and only the manufacturing method of the adsorption module 1 is different. The manufacturing process of the adsorption module 1 will be described with reference to FIG.

  In the filling step (S220), only copper powder is filled. Next, the filled copper powder is compressed using a compression jig or the like.

  In the brazing step, the parts constituting the adsorption module 1 are brazed (joined), the filled metal powder 23b is sintered, and the sintered body of the metal powder 23b and the heat medium tube 21 are sintered. Bonding (joining) is performed.

  After the brazing step is completed, a step (S520) of fixing the adsorbent 24 inside the sintered body (porous heat transfer body) is performed. In the adsorbent filling step of step S520, the adsorbent slurry (liquid) in which the adsorbent 24 is dispersed in the dispersion medium is introduced from the adsorbed medium inflow pipe 36 or the adsorbed medium outflow pipe 37, and the porous heat transfer body 23 is obtained. The adsorbent 24 is filled in the pores 23a. Thereafter, when the adsorbent slurry is dried, the adsorbent slurry is fixed inside the porous heat transfer body 23, and the adsorbent 24 can be brought into a state capable of exhibiting an adsorbing action.

  Thereby, a uniform adsorbent packed layer can be easily formed on the heat transfer surface inside the porous heat transfer body 23. Moreover, in order to put the adsorbent 24 into the furnace in a state where it is filled, the adsorbent 24 needs to have heat resistance. However, in this embodiment, the adsorbent 24 is filled after the porous heat transfer body 23 is formed. Even if there is no adsorbent 24, the manufacturing method of this embodiment can be applied.

(Third embodiment)
In the case where the porous heat transfer body 23 and the adsorbent 24 are provided in the peripheral portion 22 of the heat medium pipe 21, the porous body 23 is a so-called heat transfer fin made of copper powder as a sintered body. The contact area with the adsorbent 24 filled in the fin is increased, and the heat transfer characteristics are improved. However, depending on the thickness of the peripheral portion 22 of the heat medium pipe 21 in the porous heat transfer body 23, the diffusion resistance of the adsorbed medium when the adsorbent 24 adsorbs / desorbs the adsorbed medium may cause The adsorption / desorption rate does not increase as intended, and as a result, the cooling performance may not be improved.

  A third embodiment of the present invention is shown in FIG. The third embodiment is applied to an adsorption module 401 further including an adsorbed medium passage 25 between the heat medium tubes 21. FIG. 9 is a cross-sectional view showing the adsorption module of the embodiment. FIG. 10 is a longitudinal sectional view as seen from X in FIG. 11A and 11B are diagrams showing the adsorption heat exchanger in FIG. 9, in which FIG. 11A is a cross-sectional view, and FIG. 11B is a cross-sectional view as seen from XIB in FIG. 11A. 12 is an enlarged view of FIG. FIG. 13 is a schematic cross-sectional view showing the adsorbent packed bed in FIG. FIG. 14 is a flowchart showing a manufacturing process for an example of the manufacturing method of the adsorption module of the present embodiment.

  In the present embodiment, as shown in FIG. 9, an adsorbed medium passage 25 through which an adsorbed medium (hereinafter, water vapor) flows is provided between the heat medium tubes 21. The cross-sectional shape of the adsorbed medium passage 25 is a circle in this embodiment, but may be any of a circle, an ellipse, and a rectangle. In the present embodiment, the adsorbed medium passage 25 is disposed in a region surrounded by the three heat medium pipes 21 in the drawing, but is not limited to three, and a plurality of heat such as four or five. It may be arranged in a region surrounded by the medium tube 21.

  The adsorbed medium passage 25 plays a role of promptly penetrating into the porous heat transfer body 23 in the peripheral portion 22 of the heat medium pipe 21 through water vapor from the evaporator on the adsorbed medium inflow pipe side during adsorption. Further, at the time of desorption, the water vapor discharged from the porous heat transfer body 23 in the peripheral portion 22 of the heat medium pipe 21 is promptly guided to the condenser on the adsorbed medium outflow pipe 37 side through the adsorbed medium passage 25. End.

  By providing the adsorbed medium passage 25 between the heat medium pipes 21 in this way, the adsorbed medium can easily penetrate into the adsorbent 24 inside the porous heat transfer body 23, and the diffusion resistance of the adsorbed medium is reduced. be able to.

  Here, as shown in FIG. 11, the adsorption heat exchanger 102 includes a heat medium pipe 21, a porous heat transfer body 23 located in the peripheral portion 22 of the heat medium pipe 21, an adsorbent 24, and a heat medium pipe. The adsorbed medium passage 25 is disposed between the two. Further, the peripheral portion 22 of the heat medium tube 21 in the porous heat transfer body 23 corresponds to an adsorbent packed layer, and this adsorbent packed layer is a porous material bonded by sintering at the peripheral portion 22 of the heat medium tube 21. This is the thickness L of the quality sintered fin (see FIG. 13).

  In setting the thickness L of the adsorbent packed bed, as shown in FIGS. 12 and 13, the penetration depth r2 of water vapor toward the heat medium pipe 21 and the distance from the heat medium pipe 21 (hereinafter referred to as heat transfer). It is preferable to arrange the adsorbed medium passage 25 between the heat medium pipes 21 so that the distance r1 is substantially equal. In this embodiment, the penetration depth r2 is a distance from the inner peripheral surface of the adsorption medium passage 25 to the outer peripheral surface of the heat medium pipe 21.

  As described above, by arranging the adsorbed medium passage 25 between the heat medium pipes 21 so that the penetration depth r2 related to the adsorption and desorption speed is substantially equal to the heat transfer distance r1, It is possible to provide a high-performance adsorption heat exchanger 2 having a small diffusion resistance and excellent heat transfer characteristics and capable of reducing the time required for adsorption and desorption.

  Next, an example of the manufacturing process of the adsorption module 1 will be described with reference to FIG. In the filling step of step S240, an adsorption medium passage jig (not shown) for providing the adsorption medium passage 25 is inserted between the heat medium tubes 21. Next, a mixture of copper powder and adsorbent 24 is filled, and the mixture of copper powder and adsorbent 24 is hardened.

  After the mixture of the copper powder and the adsorbent 24 is hardened, the adsorption medium passage jig is wiped off to secure a hole (space) in the adsorption medium passage 25.

  The adsorbed medium passage 25 may be inserted with a jig that opens a hole in the adsorbed medium passage 25 at the same time when the copper powder and the adsorbent 24 are filled and pressurized and hardened.

  By such a manufacturing method, the step of positioning the copper powder and the adsorbent 24 on the peripheral portion 22 of the heat medium pipe 21 in the housing 3 and the step of positioning the adsorbed medium passage 25 between the heat medium pipes 21 are performed. Since it is carried out by the filling process, excellent productivity can be improved.

  Further, in the filling step, an adsorbed medium passage jig for providing the adsorbed medium passage 25 is disposed between the heat medium tubes 21. The space for the adsorbed medium passage 25 can be secured by simply inserting the adsorbed medium passage jig into the metal powder 23 b and the adsorbent 24 mixed in the peripheral portion 22 of the heat medium pipe 21.

(Other embodiments)
(1) In the present embodiment described above, the heat medium pipe and the casing are cylindrical. The heat medium tube and the housing are not limited to this, and may have any shape such as an elliptical shape and a rectangular shape.

  (2) In the present embodiment described above, the shape of the metal powder has been described as a fibrous shape. However, the shape is not limited to this, and may be any shape of a powder shape, a particle shape, and a fibrous shape.

  (3) In the third embodiment described above, the cross section of the adsorbed medium passage 25 is circular. However, the cross section is not limited to this, and may be elliptical or rectangular.

It is an external view which shows the adsorption | suction module of 1st Embodiment of this invention. It is the cross-sectional view seen from II in FIG. It is the longitudinal cross-sectional view seen from III in FIG. FIG. 3 is a schematic cross-sectional view showing an adsorbent packed layer in FIG. 2. It is a flowchart which shows a manufacturing process about an example of the manufacturing method of the adsorption | suction module of 1st Embodiment. It is a cross-sectional view which shows the adsorption | suction module of 2nd Embodiment. It is a figure explaining the manufacturing process concerning the manufacturing method of the adsorption | suction module of 2nd Embodiment, Comprising: It is typical sectional drawing seen from VII in FIG. It is a flowchart which shows a manufacturing process about an example of the manufacturing method of the adsorption | suction module of 2nd Embodiment. It is a cross-sectional view which shows the adsorption | suction module of 3rd Embodiment. It is the longitudinal cross-sectional view seen from X in FIG. It is a figure which shows the adsorption heat exchanger in FIG. 9, Comprising: Fig.11 (a) is a cross-sectional view, FIG.11 (b) is sectional drawing seen from XIB in Fig.11 (a). FIG. 10 is an enlarged view of FIG. 9. FIG. 10 is a schematic cross-sectional view showing the adsorbent packed bed in FIG. 9. It is a flowchart which shows a manufacturing process about an example of the manufacturing method of the adsorption | suction module of 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Adsorption module 2 Adsorption heat exchanger 21 Heat medium pipe 22 Peripheral part 23 Porous heat transfer body (porous sintered fin, sintered body)
24 Adsorbent 25 Adsorbed medium (water vapor) passage 3 Housing 31 Housing body 32, 33 Sheet 32a, 33a Through hole 34 Lower tank (tank)
35 Upper tank

Claims (13)

It has a plurality of heat medium tubes (21) through which a heat exchange medium flows in a housing (3) capable of maintaining the inside in a vacuum, and pores (23a) are formed in the peripheral portion (22) of the heat medium tubes (21). An adsorption module (1) provided with a porous heat transfer body (23) having an adsorbent and an adsorbent (24) filled in the pores (23a),
In the porous heat transfer body (23), the metal powders are bonded to each other by sintering by mixing and heating any of powdered, particulate, and fibrous metal powders with the adsorbent (24). In addition, the adsorbent (24) is filled in the pores (23a) formed by metal bonding of the metal powders, and the heat medium pipe (21 made of the same first metal as the metal powders) ) To form a metal bond,
The housing (3) is formed of a second metal having a melting temperature higher than the sintering temperature of the metal powder,
Adsorption module, characterized in that is insulated by said porous heat transfer member (23) and before Kikatamitai (3) Not metallically bonded. The housing (3) is configured such that an internal housing space is partitioned by a plurality of members brazed to each other by a brazing material,
The adsorption according to claim 1, wherein the metal powder of the porous heat transfer body (23) is configured such that the sintering temperature is the same as the brazing temperature of the brazing material. module. The first metal is copper or copper metal;
The second metal is stainless steel or iron,
The gap (δ) is provided between the porous heat transfer body (23) and a wall surface in the housing (3). Adsorption module.   4. The porous heat transfer body (23) according to claim 1, wherein the porous heat transfer body (23) has a shape formed by a wall surface in the housing (3). Adsorption module.   The adsorption module according to any one of claims 1 to 4, wherein the casing (3) is cylindrical.   6. The adsorption according to claim 1, wherein an adsorption medium passage (25) through which the adsorption medium flows is provided between the heat medium pipes (21). module. Penetration depth at which the adsorbed medium penetrates toward the heat medium pipe (21) from the inner peripheral surface of the adsorbed medium passage (25) to the outer peripheral surface of the adjacent heat medium pipe (21). (R2)
The adsorbed medium passage (25) is interposed between the heat medium pipes (21) so that the penetration depth (r2) and the heat transfer distance (r1) from the heat medium pipe (21) are substantially equal. The adsorption module according to claim 6, wherein the adsorption module is arranged. In the adsorption module (1) according to any one of claims 1 to 7,
The casing (3) is configured to enclose the medium to be adsorbed therein and to connect the external evaporator and condenser and the medium to be adsorbed so as to be able to flow. An adsorption module, wherein the adsorbed medium flows in and the adsorbed medium flows out toward the condenser when desorbing. A heat medium pipe (21) through which a heat exchange medium flows, and any one of powder, particles, and fibers sintered and bonded as a porous heat transfer body (23) to the heat medium pipe (21), The adsorbent (24) present in the peripheral portion (22) of the heat medium pipe (21) made of the same metal as the metal powder and the metal powder made of copper or copper metal is made of stainless steel or iron. In the manufacturing method of the adsorption module provided inside the housing (3) formed of the second metal,
An assembly step of disposing and assembling the heat medium pipe (21) inside the housing (3);
The metal powder and the adsorbent (24) are mixed and put into the housing (3), and the metal powder and the adsorbent (24) are placed in the peripheral portion (22) of the heat medium pipe (21). A filling step to be positioned;
A housing forming step before brazing for closing the filling port containing the metal powder and the adsorbent (24) in the filling step to form a housing before brazing;
By heating the casing before brazing in a furnace, the metal powder is sintered, the metal powders are metal-bonded to form the porous heat transfer body (23), and the porous A brazing step of metal-connecting the heat transfer body (23) to the heat medium pipe (21) and brazing the heat medium pipe (21) to the housing (3);
The manufacturing method of the adsorption module characterized by comprising. The adsorption module according to claim 9, further comprising an adsorbed medium passage (25) disposed between the heat medium pipes (21),
The filling step includes
The metal powder and the adsorbent (24) are mixed and put into the housing (3), and the metal powder and the adsorbent (24) are placed in the peripheral portion (22) of the heat medium pipe (21). Position
And the adsorption | suction medium channel | path (25) is located between the said heat-medium pipe | tubes (21), The manufacturing method of the adsorption module characterized by the above-mentioned.   The method for manufacturing an adsorption module according to claim 10, wherein in the filling step, a jig for providing the adsorption medium passage (25) is arranged between the heat medium pipes (21).   The adsorption temperature according to any one of claims 9 to 11, wherein a melting temperature of the brazing material used for brazing in the brazing step is in a range of 700 to 1000 ° C. Module manufacturing method.   The adsorbed medium passage (25) is a through-hole formed in the porous heat transfer body (23) in parallel with the heat medium pipe (21). Adsorption module.

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