Abstract:
The present invention concerns a cooling or heating system including at least a compressor ( 10 ), a coolant tank/accumulator ( 4 ), a condenser ( 11 ), an inspection glass device with ejector pump ( 1, 2 ) for circulation and control of coolant, coolant and a vaporizer ( 13 ). The invention is characterized essentially in that the system comprises: a connection ( 8 ) to the ejector pump ( 1, 2 ), for intake of condensate from the condenser ( 11 ), an exit connection ( 9 ) from the ejector pump ( 1, 2 ), for connection to the vaporizer ( 13 ) and means ( 3 ) for visually controlling the ejector pump ( 1, 2 ). The invention also concerns a device ( 12 ) for controlling the coolant of a cooling or heating apparatus.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is an U.S. national phase application under 35 U.S.C. §371 based upon co-pending International Application No. PCT/SE2006/001245 filed on Nov. 3, 2006. Additionally, this U.S. national phase application claims the benefit of priority of co-pending International Application No. PCT/SE2006/001245 filed on Nov. 3, 2006 and Sweden Application No. 0502488-0 filed on Nov. 10, 2005. The entire disclosures of the prior applications are incorporated herein by reference. The international application was published on May 18, 2007 under Publication No. WO 2007/055635 A1. 
     TECHNICAL FIELD 
     The present invention concerns a cooling or heating system including at least a compressor, a condenser, a tank/accumulator and a vaporiser. The invention also concerns a device for use in such a system. 
     STATE-OF-THE-ART 
     On the market there are many different systems for circulation of coolants in flooded evaporators for cooling systems, freezer systems, heat pump systems. The systems are used for cooling and heating purposes. 
     However, the circulation systems that are used are often complicated and have large volumes and are thereby needlessly expensive. The size and complexity of the systems also entails that their usefulness and effectiveness is lower than expected. Below some already known systems and apparatus that have some of the above mentioned disadvantages will be briefly described. 
     US2004/0255612 A1 and US2005/0204771 A1 concern different ejector systems that circulate coolant liquid on evaporation surfaces by sucking in liquid mixed gas from vaporisers and thereafter separating the liquid gas mixture in a tank/accumulator. Circulation depends on pressure maintenance across the vaporiser, among other things, the ejector pump&#39;s capacity is affected significantly also by the quality of the sucked in liquid gas mixture. The systems include inspection glasses for checking the amount of coolant in the system. 
     U.S. Pat. No. 5,247,813 A describes inspection glasses mounted in the suction channel from the accumulator/tank. 
     JP7043052 describes an inspection glass mounted on the coolant tank after the condenser for checking the amount of coolant in the cooling system and an inspection glass mounted on the channel after the coolant tank for detection of the coolant content in the cooling system. 
     The above mentioned documents are all provided with some drawbacks in that they do not see to that the amount and quality of the coolant can be controlled in a satisfying manner. 
     There is thus a need of a system that solves the problems of the above said systems in a simple flexible and easy way. 
     SUMMARY OF THE INVENTION 
     A purpose of the present invention is therefore to, among others; solve the above mentioned problem by simple and effective means. 
     The said purpose is achieved in a cooling or heating system comprising a connection to the ejector pump, for intake of condensate from the condenser, an exit connection from the ejector pump, for connection to the vaporiser, and means for visually controlling the ejector pump. Preferred embodiments are set forth in the associated dependent claims. 
     The invention also relates to a device for controlling the coolant of a cooling or heating system comprising an ejector pump, means arranged to enable visual control of the ejector pump, a connection arranged for intake of condensate from a condenser, and an exit connection arranged for connection to a vaporiser. 
    
    
     
       BRIEF DESCRIPTION OF THE FIGURES 
       In the following the invention will be described in a non-limiting way and by way of illustration with reference to the attached figures in which: 
         FIG. 1  shows an inspection glass device with ejector pump connected to the tank according to a preferred embodiment according to the present invention in section from the side and with fittings. 
         FIG. 2  shows an inspection glass device with ejector pump connected to the tank according to a preferred embodiment according to the present invention from the front with fittings. 
         FIG. 3  shows an inspection glass device with ejector pump with an alternative connection to the tank according to a preferred embodiment according to the present invention in section from the side with fittings. 
         FIG. 4  shows an inspection glass device with ejector pump with an alternative connection to the tank according to  FIG. 3  according to a preferred embodiment of the present invention from the front with fittings. 
         FIG. 5  shows a coolant system for cooling or heating purposes with an inspection glass device with ejector and bubble separation according to the present invention mounted on the tank. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In  FIGS. 1-5  an inspection glass device is shown equipped with a visible ejector pump  1 ,  2  with spray nozzle  1  and diffuser  2  for heating, cooling, or freezing systems. The ejector pump is used in flooded evaporator systems for cooling or heating purposes. With diffuser is meant a device that under increased pressure decelerates a flowing medium. With evaporating and condensing media for cooling or heating purposes, the ejector pump  1 , 2  acts as an expansion device. 
     Apart from the actual inspection glass  3  and ejector pump  1 ,  2  the inspection glass device  12  consists of: a connection  7  for the tank with coolant on the opposite side of the glass  3  for communication of coolant between the tank  4  and the ejector pump  1 ,  2 , a connection for the coolant inlet  8  directly from the condenser alternatively after a choke apparatus/expansion apparatus  14 , a connection  9  for coolant for connection to the vaporiser. The connection  7  between the tank  4  and the ejector pump  1 ,  2  is preferably shaped so that the coolant without difficulty can move between the tank and the area around the pump. The ejector nozzle  1  is shown in the drawings as a fixed orifice expansion device without the possibility of modulation, but it can also consist of a flow regulating spray nozzle for control of the amount of coolant. The control signal to the ejector nozzle can for instance be the control signal described in the Applicant&#39;s own application PCT/SE2006/000680 where in this case the expansion apparatus&#39; spray nozzle is arranged in the inspection glass apparatus. 
       FIG. 5  shows an example of a cooling/heating system with compressor  10 , condenser  11 , tank/accumulator  4 , inspection glass device, ejector pump device and gas separation  12  according to a preferred description, vaporiser  13 , coolant pipe and coolant with bubbles inside the inspection glass. 
     When the ejector nozzle  1  is pressurised and coolant condensate/liquid gas mixture from the condenser  11  flows through it, it leaves the nozzle mouth and expands thereafter with high speed jet. The coolant condensate/liquid gas mixture is formed by the nozzle to a jet that because of the nozzle&#39;s  1  design and placement is directed into the diffusor  2 . Coolant  6  from the tank  4  is sucked into the jet and mixed with the coolant condensate jet from the nozzle  1 , whereafter the mixture is pressed into the ejector diffusor  2  after which mixing of the two liquids/gas mixtures takes place. When the mixture has taken place there is also a pressure increase of the sucked in liquid from the tank  4 . The mixture is led thereafter via the connection  9  into the pipe or channel to the vaporiser  13  whose function is to take up heat from the environment and vaporize coolant liquid. Between the condenser  11  and the ejector nozzle  1 , whereafter the refrigerant expands, can as an alternative, an expansion apparatus  14  be arranged as a choke complement to the ejector pump nozzle. 
     The inspection glass  3  in the device  12  according to the invention provides good control of the coolant liquid to the ejector pump  1 ,  2 . The amount of gas bubbles  5  formed around the ejector pump  1 ,  2  is led effectively away via the tank connection  7  to the tank  4 . The bubbles are led away due to gravity. Therefore it is preferable if the ejector pump  1 , 2  is arranged in, or in connection with, the lower part of the tank  4 . The amount of evaporated liquid formed in the space around the ejector pump  1 ,  2  is led into the coolant tank  4  whereby the ejector pump&#39;s  1 ,  2  intake receives a lesser quantity of gas bubbles and a larger quantity of liquid in the coolant whereby the mass flow increases. 
     Using the inspection glass provides a lot of advantages to the system in regards to controlling or inspecting the coolant, the ejector pump  1 , 2  and/or the gas bubbles. The gas bubbles may e.g. appear due to condensate heat. As mentioned above, the device is preferably arranged in, or in connection with, the lower part of the tank  4 . This causes gas bubbles to be diverted from the ejector pump&#39;s intake and into the tank without disturbing the pump&#39;s intake of coolant from the tank. This would of course be achieved even by constructing the device without visual inspecting means  3 . However, this would cause a lot of modifications to the system in order to control the coolant and the function of the pump, e.g. providing sensors for measuring temperature and pressure, etc. Providing the ejector pump  1 , 2  in the lower part of the tank  4  makes it possible to provide the ejector pump  1 ,  2  with coolant containing a less amount of gas than if this is placed such that cavitations appear. 
     The present invention makes it possible to decrease unnecessary power losses for ejector pumps when they are used for coolant liquid circulation and wet evaporation heat exchanger by gas bubble separation in the coolant liquid. 
     The invention also makes it possible to visually check that there is a sufficient quantity coolant at the ejector in order that the pump function works well, as well as checking the degree of filling of coolant in the cooling system. It also makes it possible to watch the liquid flow to the ejector in such a way that the system is started up and functions well with regard to access to coolant and the presence of gas at the ejector pump. 
     The invention shall be applied to cooling and heating systems with vaporising/condensing coolants as the working medium. The inspection glass device with ejector pump according to the invention can be applied to all types of cooling system with wet evaporators, such as air-conditioning, heat pump, process and apparatus cooling systems that use piston compressors, screw compressors, scroll compressors, centrifugal compressors, rotation compressors or some other type of compressor and all types of coolants for heat exchange by vaporization/condensation. 
     Of course the invention is not limited to the embodiments described above and illustrated in the attached drawings. Modifications are feasible, especially with respect to the different parts&#39; characteristics, or by using comparable techniques, without on that account departing from the area of protection given in the patent claims. 
     REFERENCE SYMBOLS 
     
         
           1  Ejector nozzle. 
           2  Ejector diffuser. 
           3  Inspection glass. 
           4  Tank/accumulator for liquid/gas evaporation side. 
           5  Gas bubbles partly formed by heat from the expansion mixture. Removed from the pump into the tank due to gravity. 
           6  Liquid for recirculation via the ejector pump to vaporiser. 
           7  Connection apparatus between the inspection glass device and the tank. 
           8  Connection of the condensate expansion mixture/condensate to ejector nozzle, incoming pressure coolant for pump function. 
           9  Connection to vaporiser, from coolant exiting ejector pump. 
           10  Compressor. 
           11  Condenser. 
           12  Device with ejector and bubble separation. 
           13  Vaporiser. 
           14  Choke apparatus/expansion apparatus