CN205279503U - Absorbed refrigeration unit integral type water flow pipeline system - Google Patents

Abstract

The utility model provides absorbed refrigeration unit integral type water flow pipeline system and use the absorbed refrigeration unit and the absorbed refrigeration matrix of water flow pipeline system, the water flow pipeline system is used for providing the business turn over pipeline of hot water, cold water and cooling water for the absorbed refrigeration unit, the absorbed refrigeration unit is equipped with a plurality of combinations face, the water flow pipeline system is in a plurality of combination faces all set up a plurality of rivers interfaces and are linked together with the external world, rivers interface on every combination face is the water inlet and the delivery port of hot water, cold water and cooling water respectively, the water flow pipeline system makes a plurality of rivers interfaces that make up on the face be in the absorbed refrigeration unit is inside to switch on each other. The utility model discloses make the water flow pipeline system standardization of absorbed refrigeration unit, it is more convenient to make the access of absorbed refrigeration unit and draw forth hot water, cold water and cooling water, make the absorbed refrigeration unit possess simultaneously can to make up, the ability of the large -scale absorbed refrigeration matrix of expanded one -tenth cooling capacity multiplication.

Description

Absorption refrigeration unit integral type current tubing system

Technical field

The utility model relates to lithium bromide absorbing type refrigeration cellular manufacture field, in particular to the integral type current tubing system of refrigeration matrix independence absorption refrigeration unit and inside thereof.

Background technology

Absorption refrigeration unit has the advantages such as energy-saving and environmental protection, is easy to use the novel energy such as sun power and industrial exhaust heat used heat, obtains continuous development. Miniaturization, family oriented will be the trend again after it is put to industrial application.

Traditional lithium bromide absorbing type refrigeration unit is generally unit work, and size, the shape of the water supply port of its outside of unit of different model or specification are not identical with model yet, and the refrigerator of this kind of unit monotype number is often according to certain specific customization. When customer need changes, or when, when the application scenario of bigger refrigeration work consumption, type often can only be changed, redesign and manufacture. So traditional each model of absorption refrigeration unit is only applicable to specific, a narrow user group, it is necessary to producing according to order, the production cycle is long, organizational resources in advance cannot carry out big production in batches, constrain the development of refrigerator industry.

Summary of the invention

The utility model, in order to solve above technical problem, one of object, is as absorption refrigeration unit provides a kind of integral type current tubing system. So-called absorption refrigeration unit, refers to have the small-sized lithium bromide absorbing refrigerator of complete refrigerating function, it is possible to be used alone, and also possesses the ability that combination is extended to extensive refrigeration matrix. Described integral type current tubing system, it is arranged on refrigeration unit housings inwall, an entirety is formed with refrigeration unit housings, for the access of absorption refrigeration unit and extraction hot water, cold water and water coolant, make water supply flexibly convenient, realize blocking, multiple stage can combine, expand refrigeration work consumption, and then form large-scale absorption refrigeration matrix. Concrete technical scheme is as follows:

A kind of absorption refrigeration unit integral type current tubing system, for the inlet and outlet piping for absorption refrigeration unit offer hot water, cold water and water coolant, described absorption refrigeration unit is provided with some combinatorial surfaces;

Described water pipe system all arranges some current interfaces at described multiple combinatorial surface and is connected with the external world;

Current interface on each combinatorial surface described is respectively water-in and the water outlet of hot water, cold water and water coolant;

Described water pipe system makes the current interface on multiple combinatorial surface in the inner mutual conduction of described absorption refrigeration unit.

Further, the fuselage of described absorption refrigeration unit is rectangular parallelepiped, and four faces up and down in described rectangular parallelepiped six outside surfaces with it are combinatorial surface; Combinatorial surface described in each all arranges current interface, is respectively hot water inlet, hot water outlet, cold water inlet, cooling water outlet, cooling water inlet and cooling water outlet.

Further, described water pipe system is by the hot water inlet's mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the hot water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cold water inlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water inlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system makes described absorption refrigeration unit all can lead in/out hot water, cold water and water coolant at the same time or separately from any one combinatorial surface.

Further, in described four combinatorial surfaces, the position of upper combinatorial surface current interface and the position mirror image of lower combinatorial surface current interface are symmetrical, so that when two described absorption refrigeration unit combine up and down, corresponding current interface can be directed at and connect.

Further, in described four combinatorial surfaces, the position of left combinatorial surface current interface and the position mirror image of right combinatorial surface current interface are symmetrical, so that when combining when about two described absorption refrigeration unit, corresponding current interface can be directed at and connect.

Further, described absorption refrigeration unit has the housing being made up of wallboard;

Described water pipe system be combined with each other in described absorption refrigeration unit housings wallboard Nei Cao road by being arranged on.

Further, described housing is made up of 12 wallboards, comprises 6 exterior panels and 6 interior wallboards.

Further, it is provided with vacuum gap between the cell wall in described groove road, for reducing the convection current between cell wall and transmissibility factor.

Further, the width of described vacuum gap is 3.5-4.5mm.

Further, the water inlet of described current interface is connected by described water pipe system with the entrance of corresponding heat exchanger tube pass;

The water outlet of described current interface is connected by described water pipe system with the outlet of corresponding heat exchanger tube pass;

By described water pipe system, can by hot water, cold water and cooling water from tandem four combinatorial surfaces to the corresponding heat exchanger tube pass of described absorption refrigeration unit.

Further, described current interface is connected with active joint, and described active joint is respectively two pass joints and cut-off joint two kinds of structures;

When connecting two pass joints, described current interface conducting; When connecting cut-off joint, described current interface is closed.

Further, described water pipe system, together with absorption refrigeration unit housings, adopts engineering plastics integral molded plastic and becomes.

The two of the purpose of this utility model, are to provide a kind of absorption refrigeration unit, and described absorption refrigeration unit is provided with some combinatorial surfaces, and described multiple combinatorial surface is equipped with some current interfaces and is connected with the external world;

Described absorption refrigeration unit is provided with absorption refrigeration unit integral type current tubing system as previously described;

Described absorption refrigeration unit integral type current tubing system is connected with described current interface.

The three of the purpose of this utility model, are to provide absorption refrigeration matrix, comprise some absorption refrigeration unit;

Described absorption refrigeration unit is provided with some combinatorial surfaces, and described multiple combinatorial surface is equipped with some current interfaces and is connected with the external world;

It is provided with absorption refrigeration unit integral type current tubing system as previously described;

Described absorption refrigeration unit integral type current tubing system is connected with described current interface.

The beneficial effects of the utility model are:

The utility model makes the water pipe system standardization of small-sized lithium bromide absorbing refrigeration unit; Make small absorption refrigerator unit; Make the access of absorption refrigeration unit and draw hot water, cold water and water coolant convenient; Make small absorption refrigeration unit possess the ability that may be combined with, the large-scale absorption refrigeration matrix of refrigeration work consumption multiplication can be extended to simultaneously.

Accompanying drawing explanation

Fig. 1 is the utility model absorption refrigeration unit three-dimensional structural representation;

Fig. 2 A is refrigeration unit upper housing exterior panel schematic appearance;

Fig. 2 B is the water flow grooves road structural representation that refrigeration unit upper enclosure inner wall plate is exposed;

Fig. 3 is refrigeration unit lower housing exterior panel schematic appearance;

Fig. 4 is the water flow grooves road structural representation that in refrigeration unit lower housing, wallboard is exposed;

Fig. 5 is refrigeration unit left shell exterior panel schematic appearance;

Fig. 6 is the water flow grooves road structural representation that in refrigeration unit left shell, wallboard is exposed;

Fig. 7 is refrigeration unit right shell body exterior panel schematic appearance;

Fig. 8 is the water flow grooves road structural representation that in refrigeration unit right shell body, wallboard is exposed;

Fig. 9 is interior wallboard connectivity slot road exposed after refrigeration unit has removed all exterior panels;

Figure 10 is interior wallboard before refrigeration unit and below.

Wherein, the mark of part parts is as follows:

Absorption refrigeration unit;

Upper housing exterior panel 110;

Lower housing exterior panel 120;

Left shell exterior panel 130;

Right shell body exterior panel 140;

The external wallboard 150 of fore shell;

Back casing exterior panel 160;

Upper enclosure inner wall plate 210;

Wallboard 410 in lower housing;

Wallboard 610 in left shell;

Wallboard 810 in right shell body;

Hot water inlet 111,311,511,711;

Hot water outlet 112,312,512,712;

Cold water inlet 113,313,513,713;

Cooling water outlet 114,314,514,714;

Cooling water inlet 115,315,515,715;

Cooling water outlet 116,316,516,716;

Hot water inlet flume road 211,411,611,811;

Hot water effluent's groove road 212,412,612,812;

Cold water enters groove road 213,413,613,813;

Cold water effluent trough road 214,414,614,814;

Water coolant inlet flume road 215,415,615,815;

Water coolant effluent trough road 216,416,616,816;

Space 230,430,630,830;

Rectangle depression 550;

The conveyer trough road 620,820 of absorbent solution;

Square elbow 910.

Front inner walls plate 1010;

Back casing inwall version 1012;

Open pore 1011,1016;

Shelves plate 1013,1014;

" it " font flowing route 1030.

Embodiment

Accompanying drawing forms the part of this specification sheets; Below with reference to the accompanying drawings various embodiment of the present utility model is described. It should be appreciated that, for convenience of description, the utility model employs the term representing direction, such as "front", "rear", " on ", D score, "left", "right" etc. various example features of the present utility model and element are described, but these direction terms are only determine according to example orientations shown in accompanying drawing. Owing to embodiment disclosed in the utility model can be arranged according to different directions, so these represent that restriction just should do not regarded as in the term in direction as explanation. In the conceived case, the identical or mutually similar Reference numeral used in the utility model, refers to identical parts.

Fig. 1 is the utility model absorption refrigeration unit three-dimensional structural representation.

Being illustrated in figure 1 single lithium bromide absorbing type refrigeration unit, it is rectangular structure, and inside is provided with the heat-exchanging parts such as revivifier, vaporizer, resorber, condenser. Its basic functional principle is: taking lithium-bromide solution+pure water as working medium pair, take pure water as chilled water, and lithium-bromide solution is absorbing liquid, relies on pure water evaporation endothermic under high vacuum environment to realize refrigeration. After refrigerant absorbs heat, evaporation becomes steam. Refrigerant vapor no longer has decalescence ability, therefore, will be absorbed by lithium-bromide solution, and then together with lithium-bromide solution thermal regeneration. Turning into refrigerant vapor after chilled water heat absorption evaporation, refrigerant vapor is condensed and again becomes liquid state again and evaporation of again absorbing heat. Chilled water heat absorption evaporation absorption and regeneration condensation is absorbed heat evaporation again, carries out refrigeration cycle so continually. Refrigeration unit makes cold water, hot water and water coolant circulates between vaporizer, revivifier, resorber, each parts of condenser and carry out heat exchange to complete cooling flow and realization obtains the energy, outwardly release of heat and outwardly supplies cold from the external world by the tubing system of hot water, water coolant and cold water respectively.

Absorption refrigeration unit shown in Fig. 1 has independent hot water, cold water, cooling water pipeline system, the absorbing liquid recycle system, is the refrigerator that a platform independent is complete, can installation and operation separately, it is provided that elementary cell refrigeration work consumption. Meanwhile, possesses again multiple-unit combination, to form the ability of large-scale combined refrigeration matrix.

For adapting to this kind of combination, the utility model is at four combinatorial surfaces of absorption refrigeration unit: be respectively arranged with hot water inlet, hot water outlet, cold water inlet, cooling water outlet, cooling water inlet and cooling water outlet on upper combinatorial surface 110, lower combinatorial surface 120, left combinatorial surface 130 and right combinatorial surface 140. Combinatorial surface 110 on Fig. 1: be respectively equipped with hot water inlet 111, hot water outlet 112, cold water inlet 113, cooling water outlet 114, cooling water inlet 115 and cooling water outlet 116 on upper combinatorial surface 110. It is provided with and 6 the identical current interfaces of upper combinatorial surface 110 in mirror image symmetry at the lower housing relative with upper combinatorial surface 110, it is provided with and 6 the identical current interfaces of right combinatorial surface 140 in mirror image symmetry at the left shell relative with right combinatorial surface 140. This kind of up and down, left and right distinguish symmetrical design so that when two absorption refrigeration unit combine in combination up and down or left and right, corresponding current interface can be aligned with each other and connect into an entirety.

By the cold water inlet on the cold water inlet 113 of current interface such as upper housing corresponding on each combinatorial surface and other surfaces together with fuselage interior pipeline communication, in fact the four-way connection on a current route is constituted, to the supply of absorption refrigeration unit inside or extraction hot water, cold water and water coolant on four combinatorial surfaces. Specifically see Fig. 2 A-Figure 10.

Fig. 2 A is refrigeration unit upper housing exterior panel schematic appearance.

Fig. 2 A shows the position relation of current interface on the upper combinatorial surface 110 of absorption refrigeration unit. Because current interface identical on different face is (see Fig. 9) of being connected in fuselage interior, for adapting to the layout of fuselage interior connecting pipe, hot water inlet 111, hot water outlet 112, cold water inlet 113, cooling water outlet 114, cooling water inlet 115 and the cooling water outlet 116 difference layout different positions on upper combinatorial surface 110, each current interface of original state is in closed state, during installation, required interface is opened in the cutting of available dedicated instrument, and connects two pass joints (not shown in FIG.); By two pass joints, outside water supply can be made to be connected with current interface and refrigeration unit internal pipeline.

Lower combinatorial surface 120 has the structure completely identical with upper combinatorial surface 110, and its current interface layout and upper combinatorial surface 110 are symmetrical in mirror image, see Fig. 3.

Fig. 2 B is the water flow grooves road structural representation that refrigeration unit upper enclosure inner wall plate is exposed.

It is the water flow grooves road forming water pipe system in upper enclosure inner wall plate as shown in Figure 2 B: hot water inlet flume road 211, hot water effluent's groove road 212, cold water inlet flume road 213, cold water effluent trough road 214, water coolant inlet flume road 215 and water coolant effluent trough road 216, and it is connected with cooling water outlet 116 with hot water inlet 111, hot water outlet 112, cold water inlet 113, cooling water outlet 114, cooling water inlet 115 respectively.

It is provided with vacuum gap 230 between hot water inlet flume road 211, hot water effluent's groove road 212, cold water inlet flume road 213, cold water effluent trough road 214, water coolant inlet flume road 215 and water coolant effluent trough Dao216Cao road cell wall, the width of vacuum gap 230 is 3.5-4.5mm, for the present embodiment, for 4.0mm, its objective is the conduction and convection coefficient reduced between tube wall, reduce thermal losses.

Fig. 3 is refrigeration unit lower housing exterior panel schematic appearance.

As shown in Figure 3, absorption refrigeration unit lower housing exterior panel is provided with 6 current joints, it is hot water inlet 311, hot water outlet 312, cold water inlet 313, cooling water outlet 314, cooling water inlet 315 and cooling water outlet 316 respectively, it is consistent with six current interfaces shown in Fig. 2 A that it arranges position, and be symmetrical arranged in mirror image, so that when two absorption refrigeration unit combine up and down, corresponding current interface can be directed at and be connected. In Fig. 3,6 each current interfaces of current interface original state are in closed state, and during installation, required interface is opened in the cutting of available dedicated instrument, and connects two pass joints (not shown in FIG.).

Fig. 4 is the water flow grooves road structural representation that in refrigeration unit lower housing, wallboard is exposed.

The water flow grooves road of water pipe system is formed: hot water inlet flume road 411, hot water effluent's groove road 212, cold water inlet flume road 413, cold water effluent trough road 414, water coolant inlet flume road 415 and water coolant effluent trough road 416, it is connected with cooling water outlet 316 with the hot water inlet 311 shown in Fig. 3, hot water outlet 312, cold water inlet 313, cooling water outlet 314, cooling water inlet 315 respectively in being illustrated in figure 4 in lower housing wallboard.

Fig. 5 is refrigeration unit left shell exterior panel schematic appearance.

As shown in Figure 5, on left shell exterior panel, it is dispersed with six current interfaces: hot water inlet 511, hot water outlet 512, cold water inlet 513, cooling water outlet 514, cooling water inlet 515, cooling water outlet 516. 6 each current interfaces of current interface original state are in closed state, and during installation, required interface is opened in the cutting of available dedicated instrument, and connects two pass joints (not shown in FIG.). The rectangle depression 550 reserved in the middle of left combinatorial surface 130 outer wall is the reserved location of board-like solution heat exchanger.

Fig. 6 is the water flow grooves road structural representation that in refrigeration unit left shell, wallboard is exposed.

It is illustrated in figure 6 in left shell wallboard and forms the hot water of water pipe system, cold water, cooling trough road: hot water inlet flume road 611, hot water effluent's groove road 612, cold water inlet flume road 613, cold water effluent trough road 614, water coolant inlet flume road 615 and water coolant effluent trough road 616, and the conveyer trough road 620 of absorbent solution. Mechanism similar as mentioned before, each water flow grooves road communicates with corresponding current interface.

Fig. 7 is refrigeration unit right shell body exterior panel schematic appearance.

As shown in Figure 7, right combinatorial surface 140 is relative with left combinatorial surface 130, its housing wallboard is provided with the current interface of 6 with left combinatorial surface 130 mirror image symmetry: hot water inlet 711, hot water outlet 712, cold water inlet 713, cooling water outlet 714, cooling water inlet 715 and cooling water outlet 716,6 each current interfaces of current interface original state are in closed state, during installation, required interface is opened in the cutting of available dedicated instrument, and connects two pass joints (not shown in FIG.). The setting of this kind of mirror image symmetry, make when right combinatorial surface 140 combines mutually as another absorption refrigeration unit of combinatorial surface with right side so that it is current interface is directed at mutually, is directly connected by simple two pass joints, and can multiple be connected, form absorption refrigeration matrix.

Fig. 8 is the water flow grooves road structural representation that in refrigeration unit right shell body, wallboard is exposed.

It is illustrated in figure 8 the hot water of wallboard in right combinatorial surface 140, cold water, water coolant water flow grooves road: hot water inlet flume road 811, hot water effluent's groove road 812, cold water inlet flume road 813, cold water effluent trough road 814, water coolant inlet flume road 815 and water coolant effluent trough road 816, they are connected with cooling water outlet 716 with the hot water inlet 711 in Fig. 7, hot water outlet 712, cold water inlet 713, cooling water outlet 714, cooling water inlet 715 respectively.

It should be noted that, the Mei Tiaocao road on different face is integrated with perpendicular type elbow adjacent both sides (or monolateral), and the groove road of the same race on the wallboard adjacent with fuselage is connected, such as, shown in Fig. 9.

In Fig. 9, square elbow 910 is connected hot water inlet flume road 211 with 811 so that four hot water inlets 111,311,511,711 on absorption refrigeration unit four combinatorial surfaces form a four-way connection together with groove road 211,411,611,811; Hot water all can be led in/out at the same time or separately from any one combinatorial surface. Interface and the groove road of other character are analogized with this.

Figure 10 is the interior wallboard of the utility model absorption refrigeration unit body front shell body and back casing.

As shown in Figure 10, the exterior panel on the body front shell body 150 of absorption refrigeration unit is removed, and namely exposes front inner walls plate 1010; Exterior panel on the fuselage back casing 160 of absorption refrigeration unit is removed, and namely exposes wallboard 1012 in back casing.

As an embodiment, in body front shell body, wallboard 1010 is provided with open pore 1011, and in the fuselage back casing corresponded, the same position on wallboard 1012 is provided with grade plate 1014 (not perforate);

Meanwhile, in body front shell body, wallboard 1010 is provided with grade plate 1013 (not perforate), and in the fuselage back casing corresponded, the same position on wallboard 1012 is provided with open pore 1016.

Open pore 1011 is the entrance port of heat exchanger tube pass fluid, and open pore 1016 is the outlet port of heat exchanger tube pass fluid.

By the combined action of open pore 1011, shelves plate 1014, shelves plate 1013, open pore 1016, tube side fluid is forced to flow through heat exchanger tube pass along " it " font runner 1030 in Figure 10. Hot water, cold water, water coolant are when flowing through revivifier, vaporizer and condensation (and absorption) device pipe journey separately, and principle is identical.

Absorption refrigeration unit of the present utility model is arranged such as Fig. 2 B, 4, 6, water pipe system described in 8, by Fig. 2 A, 3, 5, 6 current interfaces on shown in 7 four combinatorial surface and extraneous (thermal source, cold source, cooling water source or other absorption refrigeration unit) it is connected and carries out supply or the extraction of current, and by hot water, cold water is connected with the gangway of water coolant with the respective interchanger of absorption refrigeration unit inside: four hot water inlets 111 of hot water, 311, 511, 711 pass through the built-in hot water inlet flume road 211 of four housing wallboards, 411, 611, 811 pipelines formed are connected with the entrance of revivifier, the pipeline that four cold water inlets 113,313,513,713 of cold water are consisted of cold water inlet flume road 213,413,613,813 is connected with the entrance of vaporizer, the pipeline that four cooling water inlets 115,315,515,715 of water coolant are consisted of water coolant inlet flume road 215,415,615,815 is connected with the entrance of condensation (and absorption) device, with reason, each water outlet port on four combinatorial surfaces is connected with the outlet of respective interchanger by the outlet conduit being attached thereto that four housing wallboards are built-in, forms complete water channel.

Absorption refrigeration unit, itself is a complete refrigerator, can independently use, it is also possible to multi-unit assembled combination. When independently installing and using, by integral type current tubing system of the present utility model, connect outside hot water, cold water, cooling water pipeline from the current interface any one side of fuselage; Time multi-unit assembled, on any one combinatorial surface up and down of refrigeration unit, multiple refrigeration unit can be spliced and combined in building blocks mode, form the refrigeration matrix of refrigerating duty multiplication. After forming matrix, the water pipe system of each refrigeration unit, except undertaking supplying water to respective interchanger of task, also undertakes the task into other refrigeration unit supply water. Form after matrix, can there is no the current interface used is selected any one or multiple interface supply or extraction hot water, cold water and water coolant from matrix.

Although the utility model will be described with reference to the embodiment shown in accompanying drawing, it is to be understood that, do not deviating under spirit, scope and the background that the utility model is instructed, absorption integral type current tubing system of the present utility model and use the absorption refrigeration unit of described water pipe system and absorption refrigeration matrix can have many change forms, such as change arranges the combinatorial surface of current interface, changes the placement position of current interface on each combinatorial surface, etc. In art technology those of ordinary skill also by recognize have different modes to change in embodiment disclosed in the utility model parameter, size, but in these spirit and scope all falling into the utility model and claim.

Claims (14)

1. an absorption refrigeration unit integral type current tubing system, for the inlet and outlet piping for absorption refrigeration unit offer hot water, cold water and water coolant, it is characterised in that:

Described absorption refrigeration unit is provided with some combinatorial surfaces;

Described water pipe system all arranges some current interfaces at described multiple combinatorial surface and is connected with the external world;

Current interface on each combinatorial surface described is respectively water-in and the water outlet of hot water, cold water and water coolant;

Described water pipe system makes the current interface on multiple combinatorial surface in the inner mutual conduction of described absorption refrigeration unit.

2. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

The fuselage of described absorption refrigeration unit is rectangular parallelepiped, and four faces up and down in described rectangular parallelepiped six outside surfaces with it are combinatorial surface; Combinatorial surface described in each all arranges current interface, is respectively hot water inlet, hot water outlet, cold water inlet, cooling water outlet, cooling water inlet and cooling water outlet.

3. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

Described water pipe system is by the hot water inlet's mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the hot water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cold water inlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water inlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system is by the cooling water outlet mutual conduction on described four combinatorial surfaces up and down;

Described water pipe system makes described absorption refrigeration unit all can lead in/out hot water, cold water and water coolant at the same time or separately from any one combinatorial surface.

4. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

In described four combinatorial surfaces, the position of upper surface current interface and the position mirror image of lower surface current interface are symmetrical, so that when two described absorption refrigeration unit combine up and down, corresponding current interface can be directed at and connect.

5. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

In described four combinatorial surfaces, the position of left surface current interface and the position mirror image of right surface current interface are symmetrical, so that when combining when about two described absorption refrigeration unit, corresponding current interface can be directed at and connect.

6. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

Described absorption refrigeration unit has the housing being made up of wallboard;

Described water pipe system be combined with each other in described absorption refrigeration unit housings wallboard Nei Cao road by being arranged on.

7. absorption refrigeration unit integral type current tubing system as claimed in claim 6, it is characterised in that:

Described housing is made up of 12 wallboards, comprises 6 exterior panels and 6 interior wallboards.

8. absorption refrigeration unit integral type current tubing system as claimed in claim 6, it is characterised in that:

It is provided with vacuum gap, for reducing the convection current between cell wall and transmissibility factor between the cell wall in described groove road.

9. absorption refrigeration unit integral type current tubing system as claimed in claim 8, it is characterised in that:

The width of described vacuum gap is 3.5-4.5mm.

10. absorption refrigeration unit integral type current tubing system as claimed in claim 1, it is characterised in that:

The water inlet of described current interface is connected by described water pipe system with the entrance of corresponding heat exchanger tube pass;

The water outlet of described current interface is connected by described water pipe system with the outlet of corresponding heat exchanger tube pass;

By described water pipe system, can by hot water, cold water and cooling water from tandem four combinatorial surfaces to the corresponding heat exchanger tube pass of described absorption refrigeration unit.

11. absorption refrigeration unit integral type current tubing systems as claimed in claim 1, it is characterised in that:

Described current interface is connected with active joint, and described active joint is respectively two pass joints and cut-off joint two kinds of structures;

When connecting two pass joints, described current interface conducting; When connecting cut-off joint, described current interface is closed.

Absorption refrigeration unit integral type current tubing system as described in 12. items as arbitrary in claim 1-11, it is characterised in that:

Described water pipe system, together with absorption refrigeration unit housings, adopts engineering plastics integral molded plastic and becomes.

13. 1 kinds of absorption refrigeration unit, it is characterised in that:

It is provided with some combinatorial surfaces, and described multiple combinatorial surface is equipped with some current interfaces and is connected with the external world;

Described absorption refrigeration unit is provided with the absorption refrigeration unit integral type current tubing system as described in item as arbitrary in claim 1-12;

Described absorption refrigeration unit integral type current tubing system is connected with described current interface.

14. 1 kinds of absorption refrigeration matrixes, it is characterised in that:

Comprise some absorption refrigeration unit;

Described absorption refrigeration unit is provided with some combinatorial surfaces, and described multiple combinatorial surface is equipped with some current interfaces and is connected with the external world;

It is provided with the absorption refrigeration unit integral type current tubing system as described in item as arbitrary in claim 1-12;

Described absorption refrigeration unit integral type current tubing system is connected with described current interface.