SE1251471A1 - Modular system for forming an expansion tank - Google Patents

Abstract

SUMMARY Module system for forming an expansion tank (1) comprising a base module (10), a first body module (30) which can be connected to the base module and a second body module (40) which can be connected to the first body module, each of these modules having a housing (11, 31, 41) and an expansion chamber (12, 32, 42) arranged inside the housing. One or more fluid passages are provided in a wall (22) of the base module housing to allow fluid exchange between the expansion chamber (12) of the base module and the expansion chamber (32) of the first body module. In addition, one or more fluid passages are provided in a wall (35) of the housing of the first body module to allow fluid exchange between the body of the body (32) and the body of the body (42) of the second body. (Fig. 5)

Description

10 15 20 25 30 large volume of air that must be compressed before the desired pressure the increase is reached, the desired boiling point increase is delayed in the coolant. For this reason, it is therefore appropriate to turn as small an expansion tank as possible. The expansion tank must, however, be large enough to accommodate the expansive coolant so that unwanted coolant leakage to the environment via the expansion tank overpressure valve is avoided. Since The coolant volume in the vehicle's cooling system varies greatly depending on vehicle type and depending on the equipment connected to the cooling system, different vehicles need different sizes of pension thoughts.

A modular system for forming an expansion tank is previously known from SE 469 849 B. This known modular system is specific designed to form a two-chamber type expansion tank and consists of two modules that are interconnected with one module placed on top of the other module.

OBJECT OF THE INVENTION The object of the present invention is to provide a further development of a modular system of the type described above for to provide a modular system with a design which in At least one aspect offers an advantage over this.

SUMMARY OF THE INVENTION According to the present invention, said object is achieved by means of a modular system having the features defined in claim 1 dragen. 10 15 20 25 30 The modular system according to the invention comprises: a base module, which has a housing and one of the housing delimited sad expansion chamber, - a first body module, which has a housing and an input expansion chamber arranged in the housing and which is interconnected connectable to the base module via a first coupling which includes a first coupling part arranged on the base module and a corresponding second coupling arranged on the first body module one or more fluid passages are arranged in one wall of the base module housing to allow fluid exchange between the expansion chamber of the base module and the first the expansion chamber of the module via this fluid passage or these fluid passages when the first body module is assembled connected to the base module, and - a second body module, which has a housing and an input expansion chamber arranged in the housing and which is interconnected with the first bodywork module via a second connection which comprises a device arranged on the first superstructure module. first coupling part and a corresponding one on the second the building module arranged second coupling part, wherein one or several fluid passages are arranged in a wall of the first the housing module housing to allow fluid exchange between it the expansion chamber of the first body module and the second the expansion chamber of the body module via this fluid passage sage or these fluid passages when the second bodywork module len is connected to the first extension module.

The basic module can be independent, ie without any add-on module connected to the base module, used as an expansion tank in one 10 15 20 25 30 cases where there is only a need for an expansion tank with small expansion volume. If you need an expansion tank with larger expansion volume, the base module can be built on with the desired number of add-on modules depending on the required expansion sion volume. This creates opportunities for a simple and cost-effectively adjust the size of the expansion to the coolant volume of the cooling system that the expansion must be connected to, whereby one and the same module set can be used to produce expansion tanks of widely differing sizes.

According to one embodiment of the invention is a pressure relief valve and a return valve arranged on said wall of the base module, wherein fluid transfer from the expansion chamber of the base module to the expansion chamber of the first body module is allowed via this pressure relief valve and fluid transfer from the first the expansion chamber of the building module to the expansion of the base module chamber is allowed via this return valve when the first the building module is connected to the base module. By the fluid exchange between the base module and the body module takes place via an overpressure valve and a return valve, only the air volume in the base module that needs to be compressed by the expander the coolant so that the desired overpressure in the cooling system is reached, even in cases where the base module is supplemented with one or more add-on modules. This makes it possible to achieve quickly the desired pressure increase in the cooling system regardless of the speak the size of the expansion tank. When the volume increase at the coolant has become so large that the entire expansion chamber of the module has been filled with coolant comes coolant via said pressure relief valve to flow over from the base module to the first 10 15 20 25 30 the add-on module. When the coolant in the cooling system eventually cools, a decrease in the volume of the coolant occurs, which in its this gives rise to a negative pressure in the expansion chamber of the base module. which can be used to suck coolant back from it the first extension module to the base module via said return valve. to.

According to another embodiment of the invention, said return valve of the base module via a line connected to the lower part of the expansion chamber of the first body module when the first body module is connected to the base module.

This ensures that the coolant that has flowed over from the base module to the first body module can be sucked into return to the base module via said return valve even when the module system is designed in such a way that the first bodywork the module is connected to the base module in the horizontal direction, ie when the base module is mounted laterally with the first mounting module dulen.

According to another embodiment of the invention, it is the side of the housing of the first body module which is intended to be facing the base module open. In this case, it works against it the first body module turns the wall of the base module housing as a partition between the expansion chamber of the base module and the expansion chamber of the first body module, wherein it the first add-on module can be given an extremely simple and cost-effective design.

According to another embodiment of the invention, it is the side of the housing of the second body module which is intended to be 10 15 20 25 30 facing the first bodywork module open. In this case, the wall facing the other body module the housing of the first body module as a partition between the expansion chamber of the first body module and the the expansion chamber of the second body module, wherein it the second extension module can be given an extremely simple and cost-effective design.

Other advantageous features of the modular system according to the invention is apparent from the dependent claims and the one below following description.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below using exemplary embodiments, with reference to the accompanying drawings.

It appears in: Fig. 1 is a perspective view obliquely from above of a base module and two bodywork modules included in a module system according to an embodiment of the present invention, Fig. 2 is a perspective view obliquely from below of the base module and the bodywork modules according to Fig. 1, Fig. 3 is a side view of the base module and the bodywork modules according to Fig. 1, Fig. 4 is a perspective view of an expansion tank formed by the base module and the body modules according to Figs. 1-3, 10 15 20 25 30 Fig. 5 is a longitudinal section through the expansion tank according to Fig. 4, and Fig. 6 is a perspective view of an expansion tank formed by the one in Figures 1-3 illustrated the base module.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION Figs. 1-3 illustrate a base module 10, a first superstructure module And a second body module 40 included in a modular system according to an embodiment of the present invention for automotive an expansion tank intended to be part of a cooling system of a motor vehicle.

The base module has a housing 11 and an external part defined by the housing. pension chamber 12 (see Fig. 5). The base module housing 11 is provided with an outlet opening 13 (see Fig. 5) which is intended to be connected to a coolant line of a cooling system to allow replacement of coolant between the expansion chamber 12 of the base module and others parts of the cooling system via this outlet opening 13. Outlet opening the unit 13 is arranged at the bottom of the expansion module of the base module. mare 12. A pipe socket 14 connected to the outlet opening 13 projects out from the underside of the housing. Said coolant line is intended to connected to this pipe socket 14.

The housing 11 of the base module is provided with two inlet openings 15 which are intended to be connected to their respective vent line at said cooling system to allow the inflow of coolant and air from 10 15 20 25 30 the vent lines to the base module expansion chamber 12 via these inlet openings. The inlet openings 15 are provided in a side wall 16 of the housing 11. Each inlet opening 15 is provided closed to a pipe socket 17 projecting from the side wall 16 of the housing.

Said vent lines are intended to be connected to these pipe sockets 17. The housing module housing 11 could alternatively be provided with only one inlet opening 15 for connection to one vent line of the cooling system.

The base module housing 11 is also provided with a closable filling. opening opening, via which coolant is introducable into the base module expansion chamber 12 so as to allow refilling of cooling liquid to said cooling system. This filling opening is closed by means of a removable cover 18.

A pressure relief valve 20 and a return valve 21 are arranged on one wall 22 of the housing module housing 11. In the illustrated embodiment the ring shape, this wall 22 is a side wall of the housing 11. In it illustrated example, said valves 20, 21 are arranged on spaced apart in each opening in said wall 22 but they could alternatively be placed close together in a common valve unit arranged in a larger opening in said wall 22. Via the pressure relief valve 20 air and cooling fluid to flow out of the upper part of the base module ex- expansion chamber 12 when, in connection with the volume of the coolant, increase, an overpressure occurs in the expansion chamber 12 which is higher than one level given by the pressure relief valve. Via the return valve 21 allows air and, where applicable, coolant to flow into the upper part of the expansion chamber 12 of the base module when in in connection with the coolant volume decrease, a negative pressure arises 10 15 20 25 in the expansion chamber 12 which is lower than one of the return valve given level.

The first body module 30 has a housing 31 and a expansion chamber 32 arranged inside the housing. the building module 30 can be connected to the base module 10 via a coupling comprising a first arranged on the base module 10 coupling part 2a and a corresponding one on the first body the module 30 arranged second coupling part 2b which is arranged to intervene with the first coupling part 2a. The first clutch the part 2a is frame-shaped and extends around the above-mentioned wall 22 of the base module housing 11, the pressure relief valve 20 and the return valve 21 is arranged inside the first coupling part 2a. The first coupling part 2a is fixedly connected to the base motor. dule housing 11 and protrudes from housing 11 perpendicular to said wall 22. The second coupling part 2b is frame-shaped and arranged to be pushed into the first coupling part 2a. The other one the coupling part 2b is fixedly connected to the body module housing 31 and designed to fit into the first coupling part 2a with a tight fit. A sealing member 3 is arranged between the two coupling parts 2a, 2b to create a fluid tight connection between the base module 10 and the superstructure module 30 when these are interconnected. In the illustrated example, this is sealing means 3 arranged in a groove on the outside of the other coupling part 2b.

The base module 10 and the first body module 30 are provided. seen with locking means 4a, 4b, 5a, 5b which can be brought into locking intervene with each other in order to lock the first attachment 10 15 20 25 30 10 the building module 30 at the base module 10 when these are interconnected put together via the coupling parts 2a, 2b.

In the illustrated embodiment, the first superstructure is the module 30 is provided with a hook-shaped locking means 4b which is arranged on the underside of the body of the body module 31. This hook-shaped locking means 4b are designed for engagement with a rod formed locking means 4a which is arranged on the underside of the base module lens housing 11.

In the illustrated embodiment, the first superstructure is the module 30 is further provided with a locking means 5b which is used arranged on the top of the body of the body module 31. This locking means 5b is designed for abutment against a locking means 5a which is arranged on top of the base module housing 11. The last two said locking means 5a, 5b are intended to be anchored to each other by means of a screw (not shown) which is insertable into a hole 6 of the locking member 5b of the body module and screwable in a threaded hole 7 of the locking member 5a of the base module.

When the base module 10 and the first body module 30 are interconnected, fluid exchange between base modules is allowed. expansion chamber 12 and the first bodywork module lens expansion chamber 32 via fluid passages formed by the pressure relief valve 20 and the return valve 21 in the wall 22 of the base the module housing 11. Air and are allowed via the pressure relief valve 20 coolant to flow from the base chamber expansion chamber 12 to the expansion chamber 32 of the first body module and via the return valve 21 air and coolant are allowed to flow from the expansion chamber 32 of the first body module 10 15 20 25 30 11 base module expansion chamber 12. To allow coolant collected at the bottom of the expansion of the first extension module chamber 32 to be sucked back into the expansion module of the base module chamber 12, the return valve 21 is connected via a line 23 the lower part of the expansion body of the first body module chamber 32.

A pressure relief valve 33 and a return valve 34 are arranged on one wall 35 of the housing 31 of the first body module illustrated embodiment, this wall 35 is a side wall of the housing 31. In the illustrated example, said valves 33, 34 arranged at a distance from each other in their respective openings in the said wall 35 but they could alternatively be placed close to each other each other in a common valve unit arranged in a larger one opening in said wall 35. Air is allowed via the pressure relief valve 33 and coolant to flow out of the upper part of the first the expansion chamber expansion chamber 32 when connected with the volume increase of the coolant, an overpressure arises in the expansion chamber 32 which is higher than one of the pressure relief valve 33 given level. Via the return valve 34, air is allowed and, where applicable coolant to flow into the upper part of the first superstructure the expansion chamber 32 of the module when in connection with the decrease in the volume of the coolant creates a negative pressure in the expansion the chamber 32 which is lower than one level given by the return valve 34.

The side of the housing of the first body module 31 which is intended to face the base module 10 is advantageously open, as illustrated in Fig. 2. In this case, the coupling part extends 2b around the edge of the opening 36 found in the first the housing module housing 31 on the open side of the housing. When 10 15 20 25 30 12 the base module 10 and the body module 30 are interconnected each other form the above-mentioned wall 22 of the base module housing 11 a partition wall between the first body module expansion chamber 32 and the expansion chamber of the base module 12.

The second body module 40 has a housing 41 and one inside the housing is arranged an expansion chamber 42. The second the building module 40 is interconnectable with the first connection the building module 30 via a coupling comprising one on it the first attachment module 30 arranged first coupling part 2a and a corresponding one on the second body module 40 arranged second coupling part 2b which is arranged to engage with the first coupling part 2a. The first coupling part 2a is frame-shaped and extends around the above-mentioned wall 35 thereof housing 31 of the first body module, the overpressure valve 33 and the return valve 34 are arranged inside the first coupling part 2a. The first coupling part 2a is fixedly connected with the housing 31 of the first body module and projecting from the housing 31 perpendicular to said wall 35. The second coupling the part 2b is frame-shaped and arranged to be pushed into the first coupling part 2a. The second coupling part 2b is fixedly connected the one with the housing of the second body module 41 and designed to fit into the first coupling part 2a with a tight fit. One sealing means 3 is arranged between the two coupling parts 2a, 2b to create a fluid tight connection between the first body module 30 and the second body module 40 when these are interconnected. In the illustrated example is this sealing member 3 arranged in a groove on the outside of the other coupling part 2b. 10 15 20 25 30 13 The first bodywork module 30 and the second bodywork the module 40 are provided with locking means 4a, 4b, 5a, 5b which can brought into locking engagement with each other so as to lock attached the second body module 40 to the first body module 30 when they are interconnected.

In the illustrated embodiment, the second superstructure is the module 40 is provided with a hook-shaped locking means 4b which is arranged on the underside of the housing of the other body module 41. This hook-shaped locking member 4b is designed for engagement with a rod-shaped locking member 4a arranged on the underside of the housing of the first body module 31.

In the illustrated embodiment, the second superstructure is the module 40 is further provided with a locking means 5b which is arranged on the top of the body of the body module 41. This locking means 5b is designed for abutment against a locking means 5a which is arranged on the top of the housing of the first body module 31. The latter two locking means 5a, 5b are intended to anchor race together using a screw (not shown) that is insertable in a through hole 6 of the second body module locking means 5b and screwable into a threaded hole 7 of the first the locking means 5a of the building module.

When the first bodywork module 30 and the second bodywork module 40 are interconnected with each other, fluid switching between the expansion chambers of the first body module 32 and the expansion chamber of the second body module 42 via fluid passages formed by the pressure relief valve 33 10 15 20 25 14 and the return valve 34 in the wall 35 of the first body The enclosure housing 31. Via the pressure relief valve 33, air and cooling fluid to flow from the expansion of the first body module chamber 32 to the expansion of the second body module air chamber 42 and via the return valve 34 air and cooling fluid to flow from the expander of the second body module chamber 42 to the expansion of the first body module sion chamber 32. To allow coolant collected at the bottom of the expansion chamber 42 of the second body module to sucked back to the expansion of the first body module chamber 32, the return valve 34 is connected via a line 37 the lower part of the expansion body of the second body module chamber 42.

A pressure relief valve 43 and a return valve 44 are arranged on one wall 45 of the housing 41. of the second body module illustrated embodiment, this wall 45 is a side wall of the housing 41. In the illustrated example, said valves 43, 44 arranged at a distance from each other in their respective openings in the said wall 45 but they could alternatively be placed close to each other each other in a common valve unit arranged in a larger one opening in said wall 45. Air is permitted via the pressure relief valve 43 and coolant to flow out of the upper part of the other the expansion chamber 42 of the body module when connected with the volume increase of the coolant, an overpressure arises in the expansion chamber 42 which is higher than one of the pressure relief valve 43 given level. Via the return valve 44, air is allowed and, where applicable coolant to flow into the upper part of the second body the expansion chamber 42 of the module when in connection with 10 15 20 25 30 15 the decrease in the volume of the coolant creates a negative pressure in the expansion chamber 42 which is lower than one level given by the return valve 44.

The side of the housing of the second body module 41 which is intended to face the first body module 30 is advantageously open, as illustrated in Fig. 2. In this case, stretch the coupling part 2b around the edge of the opening 46 which is is located in the housing of the second body module 41 on the open side of the housing. When the bodywork modules 30, 40 are interconnected laid together form the above-mentioned wall 35 of it the housing 31 of the first body module has a partition wall between it the expansion chamber 42 of the second body module and the expansion body of the extension module 32.

In the illustrated embodiment, the second extension has module 40 has the same design as the first extension The module system may also include one or more additional add-on modules with the same design as those first and second add-on modules 30, 40 to do so possible to connect a larger number of add-on modules to formation of a larger expansion tank.

Fig. 6 illustrates an expansion tank 1 formed by the one shown in Figs. said the base module 10. In this case, it would go to the return valve 21 connected line 23 may be removed.

Figures 4 and 5 illustrate an expansion tank 1 formed by the base module 10 and the two body modules 30, 40 shown in Figs 1-3. In this, the line 47 connected to the return valve 44 would possibly be removed. 10 15 20 25 30 16 In order to facilitate the attachment of an ex- expansion tank 1 in a motor vehicle, the base module 10 is advantageous provided with one or more brackets 24 arranged on the outside of base module housing 11.

In the illustrated embodiment, the base module 10 and the building modules 30, 40 a rectangular cross-sectional shape. The could, of course, be designed differently.

In the illustrated embodiment, the coupling parts 2a, 2b of the base module 10 and the body modules 30, 40 rectangular teach. However, the base module 10 could be an alternative connectable to the first body module 30 via a coupling consisting of two circular coupling parts, which pelvis could be threaded to form a screw connection or designed to form a bayonet coupling. On the equivalent In this way, two add-on modules 30, 40 could be interconnected. connectable to each other via a coupling consisting of two circular ones coupling parts, which for example could be threaded for to form a screw coupling or designed to form a bayonet coupling. In the case where the coupling parts form a screw or ion connection, the modules 10, 30, 40 do not need to be provided with some separate locking means 4a, 4b, 5a, 5b.

In the illustrated embodiment, the base module 10 and the building modules 30, 40 are designed to be connected to each others laterally, ie in the horizontal direction. As an alternative would however, the base module and the add-on modules can be designed made to be connected to each other in height, ie in vertical 10 17 ning. In the latter case, the pressure relief valves and return the valves be arranged on the top of the base module and the enclosures of the bodywork modules.

The modular system according to the invention is particularly intended to be used used to form an expansion tank for a cooling system of a heavy motor vehicle, such as, for example, a bus, a towing vehicle or a truck.

The invention is of course not in any way limited to those above described embodiments, without a variety of possibilities for specifications thereof should be apparent to one skilled in the art. without departing from the invention basic idea such as this is defined in the appended claims.

Claims (1)

18 PATENT REQUIREMENTS A load module system for forming an expansion tank (1) intended to be included in a cooling system of a motor vehicle, the module system comprising: - a base module (10), which has a housing (11) and one of the housing delimited expansion chamber (12), and - a first body module (30), which has a housing (31) and an expansion chamber (32) arranged inside the housing and which can be connected to the base module (10) via a first coupling which comprises one on the base module (10) arranged first coupling part (2a) and a corresponding second coupling part (2b) arranged on the first superstructure module (30), one or more fluid passages being arranged in a wall (22) of the housing (11) of the base module for to allow fluid exchange between the expansion chamber (12) of the base module and the expansion chamber (32) of the first body module via this fluid passage or these fluid passages when the first body module (30) is connected to the base module (10), characterized in that: t comprises a second body module (40), which has a housing (41) and an expansion chamber (42) arranged inside the housing and which can be connected to the first body module (30) via a second connection which comprises one on the first body module (30) arranged first coupling part (2a) and a corresponding second coupling part (2b) arranged on the second body module (40), and - that one or more fluid passages are arranged in a wall (35) of the housing (31) of the first body module for allow fluid exchange between the expansion chamber (32) of the first superstructure module and the expansion chamber (42) of the second superstructure module via this fluid passage or these fluid passages when the second superstructure module (40) is connected to the first superstructure module ( 30). . Modular system according to claim 1, characterized in that a pressure relief valve (20) and a return valve (21) are arranged on said wall (22) of the housing (11) of the base module, fluid transfer from the expansion chamber (12) of the base module to the first the expansion chamber (32) of the superstructure module is allowed via this pressure relief valve (20) and fluid transfer from the expansion chamber (32) of the first superstructure module to the expansion chamber (12) of the base module is permitted via this return valve (21) when the first superstructure module (30) is connected to the base module (10). . Modular system according to claim 2, characterized in that said return valve (21) of the base module (10) is connected via a line (23) to the lower part of the expansion chamber (32) of the first superstructure module when the first superstructure module (30) is connected with the base module (10). . Modular system according to any one of claims 1-3, characterized in that a pressure relief valve (33) and a return valve (34) are arranged on said wall (35) of the housing (31) of the first superstructure module, wherein fluid transfer from the first the expansion chamber (32) of the superstructure module to the expansion chamber (42) of the second superstructure module is permitted via this pressure relief valve (33) and fluid transfer from the expansion chamber (42) of the second superstructure module to the expansion chamber (32) of the first superstructure module is permitted via this return valve (34) when the second body module (40) is connected to the first body module (30). . Modular system according to claim 4, characterized in that said return valve (34) of the first superstructure module (30) is connected via a line (37) to the lower part of the expansion chamber (42) of the second superstructure module when the second superstructure module (40) is connected to the first body module (30). . Modular system according to one of Claims 1 to 5, characterized in that the side of the housing (31) of the first body module which is intended to face the base module (10) is open. . Modular system according to one of Claims 1 to 6, characterized in that the side of the housing (41) of the second superstructure module which is intended to face the first superstructure module (30) is open. . Modular system according to any one of claims 1-7, characterized in that the housing (11) of the base module is provided with an outlet opening (13) which is intended to be connected to a coolant line of said cooling system to allow exchange of coolant between the expansion chamber (12) and the base module. other parts of the cooling system via this outlet opening (13). . Modular system according to any one of claims 1-8, characterized in that the housing (11) of the base module is provided with an inlet opening 21 (15) which is intended to be connected to a vent line of said cooling system to allow inflow of coolant and air from this vent line to the expansion chamber (12) of the base module via this inlet opening (15).