DE3703261A1 - IMPROVED PUMP FOR A COMBUSTIBLE GAS-AIR MIXTURE - Google Patents

Description

The present invention relates to an improved one Pump for moving a gaseous fluid from one Inlet through an impeller chamber to an outlet a motor-driven shaft that is held by a bearing is a pump impeller that is on the shaft in the Impeller chamber is attached, and a seal is on points that operationally in a normal seal arrangement around the shaft between the pump impeller and the camp is arranged, and accordingly normal any leakage of the gaseous fluid from the flue gelrad chamber to the rear along the shaft below tie up with a department around the shaft that  one side of the seal and the other set side of the camp is limited, for the purpose of absorbing any gaseous fluid after exits along the shaft because the seal wears when the pump is operating.

With pump arrangements for flammable, gaseous fluids, Gas or air mixtures are essential nis to prevent any leakage of the mixture because otherwise there is a risk of explosion, the working environment becomes uncleaned or other impairments of utility pump.

The gas-air leakage caused by leaks Draining the mixture into the atmosphere is not a problem acceptable solution to the problem mentioned, since in in this case the environment would be polluted. It is therefore provided effective control over any leaks Gas-air mixtures to get what was in the past should be achieved that the pumping speed the pump was used for this. This solution has always been but not without sacrificing efficiency and efficiency Pump function possible.

In conventional generic devices, such as in the US-PS 27 84 672 described, the pumping speed the pump can be used to flow fluid from behind to produce the pump impeller in the impeller chamber Significantly, this was pumping absorbency not previously used effectively to reduce the disadvantage Effects of leakage of flammable fluids under control to bring, for pumping this type usually be used.  

For example, such as the fluid pump in US Pat 27 84 672 teaches that suction pressure is used effectively are created around a desired flow of cooling fluid behind the pump impeller to the inlet who used However, it is for reasons that are discussed below should not be readily apparent, that it is also possible to use the suction pressure to Leakage of a gas-air mixture from behind the pumps impeller seal to the inlet.

For a better understanding of the Schwie occurring The following is the principle of that in US Pat 27 84 672 described pump based on drawings explained.

Reference is first made to FIGS. 1 and 2A.

It shows:

Fig. 1 is a rear view of a generic pump showing the inlet and outlet, the pump being constructed so that the improvements described in the present invention can be made on it, and

Fig. 2A is a side view, partly in section, of a conventional pump, wherein the internal structure along the Schnittli never 2-2 in FIG. 1 explained, and for purposes of illustration of sub internal structure eliminated forth kömmlicher pumps with the erfindungsge MAESSEN improvement is cited.

Reference numeral 10 denotes a conventional pump of the type which is usually used for pumping combustible gas-air mixtures, the mixture passing through an inlet 12 along a channel 60 into the impeller chamber 14 , in which it is compressed to a higher pressure , and then discharged through outlet 16 to the location where it is needed. As shown in FIG. 2A, the pump 10 includes a motor 18 with a motor shaft 20 which is held by a bearing 22 which is embedded in a connecting wall 24 of the motor housing 26 . Furthermore, an impeller 28 of conventional, well-known type is mounted on the end of the motor shaft 20 in the impeller chamber 14 .

For the normal prevention of leaks of the gas-air mixture from the impeller chamber 14 to the rear along the shaft 20 , a seal 30 is typically provided which seals the shaft 20 at a point 32 . As described in FIG. 2A and in the aforementioned US-PS 27 84 672, a department 34 is typically provided between the seal 30 and the bearing 22 . In fact, compartment 34 is typically provided with an opening 36 on seal 30 on one side and an opening 38 on bearing 22 on the other side. Furthermore, it is the connection between the department 34 and the bearing 22 through the opening 38 which represent the physical conditions which fundamentally complicate the effective use of the suction pressure of the impeller chamber 14 in a conventional manner to any leakage of the gas-air -Mixture that has passed the device 30 backwards along the shaft 20 , back to the department 34 , as will be explained in more detail below.

More specifically, and although not shown in Fig. 2A, it is obviously suggested by conventional generic devices, again exemplified by US Patent No. 27 84 672, that a passage between the department 34 and the inlet 14 can be established with With the aid of which the impeller chamber suction can act on the compartment 34 to reduce leakage of the gas-air mixture that has passed the seal 30 . However, it must be appreciated that during the first time the pump 10 is used , the seal 30 effectively prevents leakage of the gas-air mixture along the shaft 20 into the compartment 34 . However, in the course of the operating time of the pump 10, the suction acting on the section 34 is no longer a usable function with regard to the return of the leakage of the gas-air mixture, whereas the effective operation of the bearing 22 is disadvantageously undermined becomes. In particular, the bearing 22 , as can be easily seen, is a ball bearing which is usually filled with grease and oil in order to facilitate the rotation of the motor shaft 20 in the opening 38 in the motor housing wall 24 . Therefore, the suction pressure acting on the section 34 , even if it is the normal pressure, will produce an undesirable tendency to move grease and oil away from the bearing 22 , which will eventually "dry out" the bearing and possibly cause malfunctions during the Operation of the pump 10 leads.

In the broadest sense, it is therefore the task of the present invention to provide an improved pump in  the pressure generated without any disadvantages in the With regard to the efficiency and operation of the pump is used to leak gas-air mixtures into the Suction chamber attributed, while the front mentioned and other disadvantages of conventional genus appropriate devices are overcome. In detail the object of the invention is suction in one To produce department behind the pump impeller in the leakage of the gas-air mixture previously collected to return this leak to the suction chamber ren, but without the bearing seal of lubricant drying out, which is necessarily in the construction the pump in the immediate vicinity of the chamber Collection of occurring leakage is arranged, what un avoidable as a result of the suction.

It is therefore an object of the invention to improve the structure of a pump constructed in a conventional manner so that unwanted leakage of fluids is closed out through the seal 30 and at the same time prevents the bearing 22 from drying out.

According to the invention, this object is achieved by a first passage from the department to the inlet of the flue gelrad chamber for generating an outflow of gas fluid that has entered the department in that suction is generated by the pump impeller and a second passage from the atmosphere the department for creating a normal inflow of air to the department at the department limits past towards and connected with the existie renden flow, during the operation of the pump whenever leakage of gaseous fluids into the  Department penetrates, the suction within the department Air from the atmosphere through the first passage in in a direction that prevents the gas feed fluid can escape into the atmosphere, and that returns gaseous fluid to the impeller chamber.

It is particularly preferred that an engine that The shaft is rotated and a housing is provided is that the motor seals and with a Opening to the outside is provided, which serves as a connection to the Atmosphere for the second outlet.

Furthermore, it is provided that the invention Device includes an impeller housing that the Defined impeller chamber and with an opening after is provided on the outside as a connection to the atmosphere serves for the second passage.

Finally, it is particularly preferred that the first Outlet of selected size is, so that in the abbey pressure is maintained that is less than the atmospheric pressure when the pump with the Nomi nal discharge pressure is operated.

The improved pump, which is the most impressive Objectives and advantages of the present invention clarify light, therefore contains the aforementioned department for Recording leakage of the gas-air mixture behind the Pump impeller, the department on one Side of a seal and on the other side of a bearing is limited that supports the shaft. The two passages provided according to the invention, of to which the first the department with the inlet of the flue gelrad chamber connects to due to the suction of the flü  gelrades of a flow of a fluid, e.g. B. Gas that in the Division penetrates while the second passage, the the atmosphere connects with the department, a nor paint flow of air into the department that produces flows past the departmental limits mentioned, in Direction of the existing river and connected with the same, whereby during the operation of the pump, if no leakage of a gas-air mixture in the department penetrates, the pull on the department less Air of the atmosphere through the first passage as through the warehouse is drawn into the department, causing the Bearing air is by-passed, that Camp but is not attacked by the suction, causing possibly grease and oil is removed from the bearing which could result in the camp drying out. However, if there is leakage from a gas-air mixture into the Department intrudes, the pressure in the department typically higher than atmospheric pressure, and the leakage is easily caused by the pump suction returned the inlet chamber.

Further features and advantages of the invention result derive from the claims and from the following Be spelling, in the two embodiments based on the Drawing are explained. It shows

Fig. 2B is the same view as Fig. 2A, namely a side view with a partial cut-out along the line 2-2 in Fig. 1, which Fig. Represents a first improved embodiment of the pump according to the invention, and

Fig. 2C is a view as in Fig. 2B, here showing a second embodiment of the improved pump according to the invention ge.

First, the first preferred embodiment of the present invention will be explained. FIG. 2B shows the same conventional or unchanged structure as has already been explained in connection with the description of the prior art with regard to pumps of the generic type with reference to FIG. 2A. For this reason, such repetitive elements are provided with the same, but simply deleted, reference numerals, so that reference numerals should not be discussed at this point either. The design features by which the pump 10 'was expanded according to the invention consist of a first passage 40 in the pump impeller housing 42 which connects one end, passage inlet 44 , with the suction or the inlet of the impeller chamber 14 '. Thus, the department via passageway 40 34 'supplied with suction, whereby a flow, indicated by 48, gaseous material in the Abbey lung 34' is generated. As already noted, there is a risk that the flow through the flow 48 may cause the bearing 22 to dry out if it is not effectively neutralized during the pumping operation of the pump 10 ', as long as there is no leakage of a gas-air mixture into the Department 34 'must be removed. During this period of pumping operation, therefore, a second passage 50 with connection to the atmosphere, passage entrance 52 is hen according to the invention, which is connected at its other end, passage exit 54 to the department 34 ', so that it generates a flowing flow 56 of air as a result of the suction pressure, which acts on the passage 34 'through the passage 40 '.

In order to summarize the improvements in the operation of the pump 10 ', it is assumed that the pump impeller 28 is set in rotation 58 , making it a combustible gas-air mixture through the inlet 12 ', the wing gel chamber 14 'and after pumps outside via the outlet 16 to a point where it is needed. During this period of pumping the pump 10 'it is further assumed that the seal 30 ' satisfactorily prevents any leakage of the combustible gas-air mixture into the department 34 '. The suction pressure, which nonetheless acts through the passage 40 on the department 34 ', the bearing 22 ' does not dry out because at this time air along the river 56 in the department 34 'causes it and thus bypasses the bearing 22 ' is, instead of the flow going through the camp, where is then made by connecting the opening 44 of the passage 40 with the flow 48 , which leads into the inlet of the impeller chamber 14 '. In this way, and in particular by generating an air flow mes over the bearing 22 ', there is no tendency to wash out the oil or fat in the bearing 22 from the same, whereby the bearing would lose its function of facilitating the rotation of the motor shaft 20 ' .

Next, it is assumed that due to the longer operation of the pump 10 'wear of the seal 30 ' occurs, whereby it is to be expected that leakage of a gas-air mixture to the rear along the shaft 20 'passes the sealing surface 32 ' by the seal 30 'is formed. The combustible gas-air mixture that collects in the department 34 'will then have a higher pressure than the atmosphere. In practice, a "rule of thumb" according to the gas-air mixture that penetrates into the department 34 'are under higher pressure than the atmosphere. This gas-air mixture of the aforementioned pressure is caused by the suction through the passage 40 to return to the inlet of the impeller chamber 14 '. In this connection, it has been found in practice that optimal results are achieved when the passage 40 has a diameter of approximately 2.3 to approximately 3.83 mm (3/32 to 5/32 inches) Diameter, which is chosen for the passage 40 , a function of the pump capacity and the back pressure and should therefore be dimen sioned that it generates a negative pressure in the chamber 34 'whenever the pump outflow is almost closed.

A second exemplary embodiment of the present invention will be explained below with reference to FIG. 2C, in which many similar structures occur which have already been described in connection with FIG. 2B and which are therefore designated by the same reference number, albeit with two lines . The main difference between the embodiment of Fig. 2C compared to that of Fig. 2B is that the motor 18 '' is not hermetically sealed in the housing 26 '', but is open to the atmosphere via the outer openings 62 , the said Openings in turn via the openings 64 make the same connection between the atmosphere and the department behind the bearing 22 'for incoming air, which corresponds to the function of the passage 50 of the embodiment of Fig. 2B. This is in the exemplary embodiment for the pump in Fig. 2C before the collapse of the sealing surface 30 '' the suction of the impeller chamber 14 '' by atmospheric air which flows along the channel 66 in the department 34 '' and is connected with the outflow from the department 34 '' through the passage 40 'towards the inlet of the impeller chamber 14 ''neutralized. Through the channel 66 , the bearing 22 '' is in turn effectively bypassed and there is therefore no tendency to remove oil or grease from the bearing 22 . In the event that the sealing surface 30 '' collapses, the suction in the department 34 '' effectively move any combustible gas-air mixture leak back into the department and then return it to the inlet of the impeller chamber 14 ''.

The in the above description, in the drawing as well as features of the Erfin disclosed in the claims can be used both individually and in any combination bination for realizing the invention in their different embodiments may be essential.  

• Reference list: 10 pump
  12 inlet
  14 impeller chamber
  16 outlet
  18 engine
  20 motor shaft
  22 bearings
  24 end wall
  26 motor housing
  28 impeller
  30 seal
  32 sealing surface
  34 department
  36 opening
  40 First passage
  42 Pump impeller housing
  44 culvert entrance
  48 river
  50 Second passage
  52 culvert entrance
  54 outlet outlet
  56 river
  58 Direction of rotation
  60 channel
  62 outside opening
  66 channel

Claims (4)

1. An improved pump for moving a gaseous fluid from an inlet through an impeller chamber to an outlet, a motor driven shaft supported by a bearing, a pump impeller mounted on the shaft in the impeller chamber, and a A seal operatively disposed in a normal sealing arrangement around the shaft between the pump impeller and the bearing to normally prevent any leakage of the gaseous fluid from the impeller chamber rearward along the shaft, with a compartment around the shaft around, which is bounded on one side by the seal and on the opposite side by the bearing, for the purpose of receiving any gaseous fluid that escapes backwards along the shaft because the seal wears out during operation of the pump, characterized by a first passage ( 40 ) from the Abtellung ( 34 ) to the inlet ( 12 ) of the impeller chamber ( 14 ) for generating an outflow outflow of the gaseous fluid that has entered the compartment by drawing suction from the pump impeller ( 28 ) and a second passage ( 50 ) from the atmosphere to the compartment to create a normal inflow of air into the compartment the department boundaries ( 30 , 22 ) past and connected to the existing flow, during operation of the pump ( 10 ) whenever leakage of gaseous fluid enters the department, the suction within the department from air from the atmosphere the first passage lets in in a direction that prevents the gaseous fluid from escaping into the atmosphere, and returns the gaseous fluid to the impeller chamber ( 14 ). 2. Improved pump according to claim 1, characterized by a motor ( 18 ) which sets the shaft ( 20 ) in rotation ( 58 ), and a housing ( 26 ) sealingly enclosing the motor with an opening ( 62 ) to the outside serves as a connection to the atmosphere for the two th outlet ( 50 ). 3. Improved pump according to claim 1, characterized in that it includes an impeller housing ( 42 ) which defines the impeller chamber ( 14 ) and is provided with an opening to the outside, which connects to the atmosphere for the second passage ( 50 ) serves. 4. Improved pump according to claim 1, characterized in that the first passage ( 40 ) is of selected size, so that in the department ( 34 ) a pressure is maintained which is less than the atmospheric pressure when the pump with the Nominal discharge pressure is operated.