Patent Publication Number: US-2010108721-A1

Title: Dispensing device for liquids

Description:
The present invention relates to a dispensing device suitable for repeatedly dispensing a predetermined amount of liquid which is supplied to the device under pressure, in which the amount of liquid dispensed by the device is determined by a timer. 
     One method for repeatedly applying a predetermined volume of liquid, such as solutions of agricultural chemicals, to a plant is to use a graduated beaker or a similar kind of container to measure the solution. This method allows for precise measurement of a liquid and allows the liquid to be applied topically, for example to the base of the plant, if desired. The advantage of this method is that the equipment is very inexpensive and that the volumes can readily be changed as required. The drawback of this method is that it is very time-consuming and that the operation of pouring a liquid from a heavy canister, which is commonplace for agricultural chemicals, into a beaker can lead to injury of the back, the lower lumbar region, the neck and the wrist. Furthermore, there is a considerable risk of exposure to the agricultural chemicals as the pouring action can result in splashing. 
     Dispensing devices which deliver a predetermined volume of liquid, typically solutions of agricultural chemicals, are known and are described, for example, in U.S. Pat. No. 4,650,099 and U.S. Pat. No. 4,821,927. These patents disclose dispensing devices which deliver a liquid which is supplied to the device under pressure within a narrow range of predetermined volumes, typically from about 1 to 20 ml. The principle used is that of positive displacement of the liquid which is essentially the same as the working of a simple syringe comprising of a plunger in a barrel. In a syringe the plunger is pulled back to load a liquid into the barrel. The liquid is then forced out of the barrel by actuating the plunger. In the dispensing devices as described in U.S. Pat. No. 4,650,099 and U.S. Pat. No. 4,821,927, the pressure of the liquid forces back the plunger thus filling the barrel which is situated within the device. This action simultaneously compresses a spring. When the trigger of the device is actuated the compressed spring pushes the plunger thus forcing the liquid out of the barrel. These devices allow for precise measurement of a liquid and allow the liquid to be applied topically, for example to the base of the plant, if desired. Furthermore, they reduce the exposure to the agricultural chemicals as the device operates as a closed system until the liquid is dispensed. The drawback of these devices is that they are restricted to dispensing only small volumes of liquid. This is because the volume that can be dispensed under the action of positive displacement is limited to the size of the spring which in turn is limited to the pressure of the liquid supplied to the device. The pumps used in conventional knapsack sprayers cannot generate the pressures required for dispensing volumes greater than about 20 ml. More powerful pumps are commercially available but are heavier and thus would introduce manual handling problems for the operator of such a dispensing device for liquids. The operator would be likely to suffer injury to his back and to suffer from fatigue if required to carry a heavy pump on his back whilst applying an agricultural liquid to a field. 
     Self-closing mechanisms which use a viscous liquid, such as paraffin, in a self-contained damping unit to repeatedly dispense a predetermined amount of liquid, are known and described in, for example, EP 0,213,102. Here a “normally closed” 2/2 valve interrupts the flow of the liquid to be dispensed. When the operator actuates the trigger against a spring the valve is opened. When the operator releases the trigger the action of the spring works to move the valve back into its closed position. This motion is slowed down by the self-contained damping unit in which the viscous liquid needs to move from one chamber to the other chamber in order for the valve to close. The timer in this type of self-closing mechanism starts to run as soon the operator releases the trigger. If the operator chooses to keep the trigger engaged for a prolonged period of time the liquid to be dispensed continues to flow through the open valve. Whilst such a self-closing mechanism could be utilised in an agricultural spraying device there are several distinct disadvantages. Firstly, the use a separate fluid in the self-contained damping unit adds to the weight of the spraying equipment. And secondly, prolonged trigger engagement leads to excess application of the agricultural liquid. 
     Certain self-closing mechanisms which use the liquid to be dispensed in an inter-connected damping mechanism to repeatedly dispense a predetermined amount of liquid, are known and described in, for example U.S. Pat. No. 5,451,030 and DE 4,323,063. Here a “normally closed” 2/2 valve interrupts the flow of the liquid to be dispensed. When the operator actuates the trigger against a spring the valve is opened and a moveable part within an internal chamber is also displaced allowing one part of the internal chamber to fill with the liquid to be dispensed. This displacement of the moveable part which is the immediate result of the operator&#39;s action resets the timer. When the operator releases the trigger the action of the spring and the pressure of the liquid to be dispensed work to move the valve back to its closed position. This motion is slowed down by the inter-connected damping mechanism in which the liquid trapped in one part of the internal chamber needs to move into the other part of the internal chamber in order for the valve to close. The timer in this type of self-closing mechanism starts to run as soon the operator releases the trigger. If the operator chooses to keep the trigger engaged for a prolonged period of time the liquid to be dispensed continues to flow through the open valve. Whilst such a self-closing mechanism with an inter-connected damping mechanism could be utilised in an agricultural spraying device there are several distinct disadvantages. Firstly, the channels connecting different parts of the internal chamber render such a mechanism vulnerable to blockage by particles. And secondly, prolonged trigger engagement leads to excess application of the agricultural liquid. Such a self-closing mechanism with an inter-connected damping mechanism is more suited to dispensing “pure” water and is commonly employed, for example, in self-closing water taps. 
     We have now invented a dispensing device suitable for repeatedly dispensing a predetermined volume of liquid which is supplied to the device under pressure which overcomes the limitations imposed on the method and devices described above. In a preferred embodiment the device enables the operator to apply a predetermined volume of the liquid for spot application of agricultural chemicals. The amount of liquid dispensed by the device is determined by a timer. The volume which is to be dispensed by the dispensing device for liquids of the preferred embodiment can conveniently be selected, typically volumes from about 10 to 1000 ml. 
     Thus, in one embodiment the invention provides a device for dispensing a predetermined amount of liquid which is supplied to the device under pressure, in which the amount of liquid dispensed by the device is determined by a timer. This can be contrasted with the devices described in U.S. Pat. No. 4,650,099 and U.S. Pat. No. 4,821,927 where the amount of liquid dispensed is determined by the volume of the barrel situated within the device. In a preferred embodiment the timer keeps the flow to the outlet valve “open”, for a predetermined length of time thus determining the amount of liquid to be dispensed by the device. 
     In another embodiment the timer comprises a piston moving within a cylinder whose speed of movement from an “open” position in which the flow to the outlet valve is “open”, to a “closed” position in which the flow to the outlet valve is “closed”, is controlled by a damping mechanism. The present invention uses a piston and cylinder assembly situated within the dispensing device for liquids to act as a timer. This can be contrasted with the device described in EP 0,213,102 where the self-closing mechanism is separate in a self-contained damping unit. The relevant time is the time that it takes for the piston to move from one extreme position (the open position) to the other extreme position (the closed position). In a preferred embodiment the damping mechanism is a liquid which is pumped by the piston through an orifice; conveniently the liquid used in the damping mechanism is the same liquid as is dispensed by the device. This can be contrasted with the device described in EP 0,213,102 where the self-closing mechanism uses a liquid other than the liquid to be dispensed to regulate the self-contained damping unit. The presence of an orifice against which the piston has to pump the liquid has the effect that the movement of the piston from one extreme position (the open position) to the other extreme position (the closed position) is hampered. The liquid, as soon as it has been pumped through the orifice, is directed so as to allow it to move away from the orifice, preferably creating minimal back pressure on the flow through the orifice. In a preferred embodiment the flow of the liquid after it has been pumped through the orifice is directed so as to allow it to be used in the spray application, preferably it is directed so as to be joined with the main volume of spray liquid metered out for dispensing. This can be contrasted with the devices described in U.S. Pat. No. 5,451,030 and DE 4,323,063 where the liquid trapped in one part of the internal chamber needs to move into the other part of the internal chamber. 
     In a further embodiment the damping mechanism is adjustable so as to vary the damping effect. The amount of resistance to the movement of the piston from one extreme position (the open position) to the other extreme position (the closed position) as the liquid is displaced from the cylinder can be adjusted by restricting the flow of the liquid displaced from the cylinder. This can be achieved by various means, for example by introducing a variable orifice (a throttle valve) at the end of the cylinder so that the flow of fluid from the cylinder is restricted. In a preferred embodiment the size of the orifice is adjustable so as to vary the damping effect. 
     In another embodiment the piston is biased towards the closed position by a biasing means. This can be achieved by various means, for example by introducing a spring into the piston and cylinder assembly. In a preferred embodiment the biasing means is a spring. 
     In a further embodiment the piston can be moved against the biasing means by liquid pressure so as to move it to the open position. This allows the timer to be reset. Preferably, the liquid used to reset the timer is the same liquid which is dispensed by the dispensing device. More preferably, the liquid used to reset the timer is under the same pressure as the liquid which is dispensed by the dispensing device. This can be contrasted with the devices described in EP 0,213,102, U.S. Pat. No. 5,451,030 and DE 4,323,063 where the timer is reset by actuation. In a preferred embodiment the piston is moved against the biasing means by liquid pressure so as to move it to the open position in which the pressure is that of the liquid supplied to the device. 
     In a further embodiment, the trigger valve is situated in the inlet channel. In a preferred embodiment, the trigger valve is a “normally open” 3/2 valve. 
     In a further embodiment, the outlet valve is situated in the outlet channel. In a preferred embodiment, the outlet valve is a “normally closed” 2/2 valve. 
     In a further embodiment, the trigger valve and the outlet valve are switched in parallel. In a preferred embodiment, the trigger valve and the outlet valve are switched in parallel and assume the opposite settings. In a more preferred embodiment the trigger valve is set to “open”, that is the liquid can flow via the inlet channel from the inlet orifice to the cylinder but not to the outlet orifice, and the outlet valve is set to “closed”, that is the liquid cannot flow via the outlet channel from the inlet orifice to the outlet orifice, when the trigger is not engaged, and conversely, the trigger valve is set to “closed”, that is the liquid can flow via the inlet channel from the cylinder to the outlet orifice but not from the inlet orifice, and the outlet valve is set to “open”, that is the liquid can flow via the outlet channel from the inlet orifice to the outlet orifice, when the trigger is engaged. 
     In a further embodiment the trigger is engaged and disengaged by the operator. Alternatively, the trigger can be engaged and disengaged by other means. 
    
    
     
       The invention will now be illustrated by means of the following non-limiting embodiment. 
         FIG. 1  is an axial section of the dispensing device for liquids in its initial position. That is the position the device assumes if it is disconnected from a source of liquid. 
         FIG. 2  is an axial section of the dispensing device for liquids before discharge. This is the position the device assumes when it is connected to a source of liquid under pressure. 
         FIG. 3  is an axial section of the dispensing device for liquids during discharge. This is the position the device assumes when the trigger has been actuated. 
     
    
    
     Block  1  is a block of material, preferably made out of metal. In a preferred embodiment block  1  is of a flattened cylindrical shape. Reference is made to the elliptical aspect and the axial aspect of block  1 . Cylinder  2  is a cavity located centrally in block  1 . Inlet orifice  3  is a cavity located towards one of the elliptical aspects of block  1 . Outlet orifice  4  is a cavity located towards the other elliptical aspect of block  1 , preferably opposite to inlet orifice  3 . The diameters of inlet orifice  3  and outlet orifice  4  are preferably the same. The diameters of inlet orifice  3  and outlet orifice  4  are preferably smaller than the diameter of cylinder  2 . Piston orifice  5  is a cavity located in block  1  effectively extending beyond inlet orifice  3  so as to connect inlet orifice  3  with cylinder  2 . The diameter of piston orifice  5  is preferably smaller than the diameter of inlet orifice  3 . Cylinder  2  and outlet orifice  4  are not connected. 
     Inlet channel  6  is a cavity connecting inlet orifice  3  and outlet orifice  4  by circumventing cylinder  2  as shown in the Figures. Preferably inlet channel  6  is a U-shaped channel. Outlet channel  7  is another cavity connecting piston orifice  5  and outlet orifice  4  by circumventing cylinder  2 , essentially mirroring inlet channel  6  as shown in the Figures. Preferably outlet channel  7  is a U-shaped channel. The diameters of inlet channel  6  and outlet channel  7  are preferably the same. 
     Cylinder  2 , inlet orifice  3 , outlet orifice  4 , piston orifice  5 , inlet channel  6  and outlet channel  7  are connected with each other and in the absence of any additional mechanical parts a liquid could move from one space to the other. 
     Piston  8  comprises four elements which are permanently attached to one another: piston head  8   a , piston shaft  8   b , piston spacer  8   c  and piston seal  8   d . These are all blocks of material, preferably made out of metal. The diameter of piston head  8   a  is marginally smaller than the diameter of cylinder  2  so as to allow piston head  8   a  to move within cylinder  2  and at the same time to form a seal. The diameter of piston shaft  8   b  and piston seal  8   d  are marginally smaller than the diameter of piston orifice  5  so as to allow these parts to move within piston orifice  5  and at the same time to form a seal when required. The diameter of piston spacer  8   c  is smaller than the diameter of piston shaft  8   b  and piston seal  8   d.    
     Spring  9  is a helical element, preferably made out of metal. The diameter of spring  9  is slightly smaller than the diameter of cylinder  2  so as to allow spring  9  to fit securely into cylinder  2 . 
     The concentric arrangement of the following elements is preferable for the efficient operation of the dispensing device for liquids: cylinder  2 , inlet orifice  3 , outlet orifice  4 , piston orifice  5 , piston  8  and spring  9 . 
     Trigger valve  10  is a “normally open” 3/2 valve which is situated in inlet channel  6  as shown in  FIG. 1 . The part of inlet channel  6  that connects inlet orifice  3  with trigger valve  10  is referred to as front inlet channel  6   a ; the part of inlet channel  6  that connects trigger valve  10  with outlet orifice  4  is referred to as rear inlet channel  6   b . In its “open” state two of the ports of a “normally open” 3/2 valve are connected with each other and the other port is blocked. Here front inlet channel  6   a  is connected to cylinder  2  and the connection to rear inlet channel  6   b  is blocked. When the 3/2 valve is actuated the connection changes and the valve is said to be in its “closed” state. Here cylinder  2  is connected to rear inlet channel  6   b  and the connection to front inlet channel  6   a  is blocked. 
     Outlet valve  11  is a “normally closed” 2/2 valve which is situated in outlet channel  7  as shown in  FIG. 1 . The part of outlet channel  7  that connects inlet orifice  3  with outlet valve  11  is referred to as front outlet channel  7   a ; the part of outlet channel  7  that connects outlet valve  11  with outlet orifice  4  is referred to as rear outlet channel  7   b . In its initial state port  1  and port  2  of a “normally closed” 2/2 valve are not connected to each other until the valve is actuated. Here front outlet channel  7   a  is not connected to rear outlet channel  7   b . When the valve is actuated front outlet channel  7   a  and rear outlet channel  7   b  are connected. Trigger valve  10  and outlet valve  11  are switched in parallel. As long as the trigger is not engaged trigger valve  10  is open and outlet valve  11  is closed; conversely when the trigger is engaged trigger valve  10  is closed and outlet valve  11  is open. 
     Throttle valve  12  is located where rear inlet channel  6   b  connects with outlet orifice  4 . Throttle valve  12  consists of a screw at the end of rear inlet channel  6   b . When the screw is “loose” the flow of liquid through throttle valve  12  is essentially unhindered; conversely when the screw is tightened the flow of liquid through throttle valve  12  is restricted. 
     The relative arrangement of the moving parts of the dispensing device for liquids, that is piston  8 , spring  9 , trigger valve  10  and outlet valve  11 , in its initial position (that is the trigger is not engaged) is shown in  FIG. 1 . In this position the flow of any liquid to outlet valve  11  is blocked by piston seal  8   d  and the setting of trigger valve  10  directs the flow of any liquid into cylinder  2 . 
     If the mechanism is attached to a source of pressurized liquid the pressure forces the liquid from inlet orifice  3  via inlet channel  6  into cylinder  2 . In doing so the liquid pushes piston head  8   a  towards piston orifice  5  thus compressing spring  9 . It is necessary for the liquid to have a minimum pressure of about 0.5 bars so as to overcome the force of spring  9 . When piston head  8   a  has assumed its final position close to piston orifice  5  as shown in  FIG. 2  the flow to outlet valve  11  is free as piston seal  8   d  no longer blocks front outlet channel  7   a . The volume of liquid now located in cylinder  2  is referred to as the fixed volume of liquid. 
     In order to dispense the liquid, the operator engages a trigger which simultaneously switches trigger valve  10  to “closed” and switches outlet valve  11  to “open” as shown in  FIG. 3 . In this position the liquid can flow freely from inlet orifice  3  to outlet orifice  4  via outlet channel  7 . This flow of liquid via outlet channel  7  is referred to as the discharge flow. At the same time piston  8  is pushed back into its initial position by the action of spring  9  and by the pressure of the liquid against piston seal  8   d . As a result the fixed volume of liquid flows from cylinder  2  to outlet orifice  4  via rear inlet channel  6   b  and throttle valve  12 . The speed with which the fixed volume of liquid is discharged is dependent on the setting of throttle valve  12  and on the pressure of the liquid. These two factors determine the time it takes for the fixed volume of liquid to be discharged from cylinder  2 . The pressure of the liquid past throttle valve  12  should be as small as possible so that it does not become a factor in determining the time it takes for the fixed volume of liquid to be discharged from cylinder  2 . 
     The predetermined volume is consequently the sum of the volume of liquid that is dispensed in the discharge flow and the fixed volume of liquid. The volume of liquid that is dispensed in the discharge flow is determined by the time it takes for the fixed volume of liquid to be discharged from cylinder  2 . The time can be conveniently adjusted by adjusting throttle valve  12 . For example, if throttle valve  12  is fully opened then the fixed volume of liquid will be dispensed quickly and thus only a small volume of liquid will be dispensed in the discharge flow. In this situation almost all liquid discharged by the present device will be the fixed volume of liquid itself. If by contrast throttle valve  12  is tightly closed then the fixed volume of liquid will be dispensed slowly and thus a large volume of liquid will be dispensed in the discharge flow. In this situation almost all liquid discharged by the present device will stem from the discharge flow. Any position between the two extremes will serve to discharge a volume between those achieved in the extreme settings of throttle valve  12 . When the pressure of the liquid is from about 1 to 5 bars, different pressures of the liquid still result in the essentially same amount of liquid being discharged at the same setting of throttle valve  12 . 
     After the predetermined volume of liquid, as determine by the setting of throttle valve  12  and the pressure of the liquid, has been discharged the operator can release the trigger which switches trigger valve  10  to “open” and switches outlet valve  11  to “closed”. This allows the cycle to repeat itself and thus for the same amounts of liquid to be dispensed repeatedly. In a preferred embodiment, trigger valve  10  remains “closed” and outlet valve  11  remains “open” after the predetermined volume of liquid has been discharged until the operator releases the trigger. 
     If the trigger is released before the fixed volume of liquid has been discharged then the flow of the liquid is interrupted as the release switches trigger valve  10  to “open” and switches outlet valve  11  to “closed”. The cycle resumes at the stage of filling cylinder  2  with liquid. The operator must ensure that the trigger is not released prematurely if he wishes to ensure accurate delivery of the predetermined volume of liquid. 
     The mechanism of the present invention does not only cover the mechanism drawn with the ratios of the elements as shown in the Figures but extends to mechanisms where the ratios of the elements are selected differently as adapted to other liquids. 
     Furthermore, the mechanism of the present invention does not only cover the mechanism as shown in the Figures but extends to mechanisms in which the concept of using a timer to control the volume dispensed from a pressurised source is employed. In particular, the present invention covers mechanisms which employ one or more of the following elements: the use of a piston and cylinder assembly to act as a timer; the use of a liquid as a damping mechanism (preferably the use of the liquid to be dispensed as a damping mechanism); the use of a liquid to reset the timer (preferably the use of the liquid to be dispensed to reset the timer). 
     The size of the various components and the diameters of the various channels and orifices are suitably chosen to reflect the kind of liquid to be dispensed (e.g. the viscosity of the liquid forming an important consideration), the pressure with which the liquid is supplied, the amounts of liquid required for metering and other factors such as how this device might be incorporated into a dispensing system. The mechanism is suitable for any liquid with has a low viscosity and is essentially free of particles. For example, the mechanism can be used to deliver fuel additives to batches of fuel, to deliver vaccination liquids for animals and to deliver beverages or fluid nutrients into containers prior to packaging. 
     Block  1  may also include additional features such as a permanent fixture attached to inlet orifice  3  and/or to outlet orifice  4 . Advantageously such a fixture or fixtures essentially extend inlet orifice  3  and/or outlet orifice  4  and allow the dispensing device for liquids to be connected to other equipment. An example for a permanent fixture is a screw fixture. This allows the other equipment to be connected and disconnected as required. The equipment to be used in connection with present dispensing device for liquids then require a complimentary fixture, in this example a nut fixture, in order to be connected to block  1 . For example, the liquid from a pressurised source could to be connected to inlet orifice  3  by connecting a hose leading off a pump which is fitted with such a nut fixture to the screw fixture at inlet orifice  3 . 
     In one embodiment the present device is used as a dispensing device for agricultural liquids. The size of block  1  is chosen so that it can conveniently be held by the operator. The volumes of liquid to be dispensed are preferably from about 10 to 1000 ml. The range of pressures at which the liquids need to be delivered is preferably from about 1 to 5 bars. The diameters of the channels and orifices are chosen to be suitable for dispensing liquids which are used routinely as agricultural liquids. For example, they can be agricultural liquids containing one or more crop protection agents, such as one or more herbicides, one or more fungicides, or one or more insecticides, and/or agricultural liquids containing one or more fertilisers. The advantage for the operator is that the agricultural liquid can be applied as a “spot application”. That means rather than applying the agricultural liquid to a whole crop, in particular the foliage, as is the case when using conventional spraying methods, here the operator can apply the liquid at the base of the plant, if it is desirable to do so. 
     The spot application of agricultural chemicals, for instance, the application of an agricultural liquid to the base of each plant, is useful as this can limit the amount of agricultural liquid wasted. For example, when spraying an agricultural chemical which is best taken up by the roots of a plant, any agricultural chemical which falls onto the foliage where the uptake is limited may be wasted. Spot application of agricultural chemicals is thus an environmentally friendly way of applying chemicals. An example of an agricultural chemical that is particularly suitable for spot application is the insecticide thiamethoxam (Actara™). Thiamethoxam (Actara™) has been shown to have very beneficial effects when applied to the base of, for example, coffee plants. 
     Conventionally spot application has been achieved in a labour intensive fashion, for example, the operator might have been required to measure out the liquid into a measuring jug and then to pour the measured liquid at the base of the plant. Also there are dispensing devices for liquids which can deliver a predetermined volume, for example, as described in U.S. Pat. No. 4,650,099 and U.S. Pat. No. 4,821,927. However, these dispensing devices can only deliver a liquid within a narrow range of predetermined volumes from about 1 to 20 ml. By contrast, as was highlighted above, the present device is capable of repeatedly dispensing volumes of up to about 1000 ml. 
     The dispensing device for liquids can be used in conjunction with a knapsack sprayer. Knapsack sprayers are commonly used in agriculture. They comprise a tank in which the operator fills with the agricultural liquid, typically in volumes of up to about 30 litres which can be easily carried by the operator, and a means of pressurizing the liquid. Inexpensive versions of knapsack sprayers typically rely on the pressure to be generated by the operator. The operator can generate a continuous pressure typically from about 1 to 3 bars. 
     Alternatively, the dispensing device for liquids can be used in conjunction with a tank. Tanks are commonly used in agriculture to carry agricultural liquids in volumes of up to about 5000 litres. The tanks can have multiple access points for individual operators to attach their equipment. For example six operators might use a single tank as a source of pressurized liquid to feed into their individual spray heads or lances. Mechanical pumps are typically used in conjunction with such tanks to exert pressures of typically from about 3 to 5 bars on the agricultural liquid. 
     In one embodiment the dispensing device for liquids further comprises a filter which is situated near or at inlet orifice  3 . The filter can be connected to block  1  permanently or can be detachable from block  1 . Filters are commonly used in connection with agriculture liquids to avoid blockage of spray heads and lances. In this instance, the liquid spraying device itself is also vulnerable to blockage by any particles introduced through the agricultural liquid. It is advantageous if the filter is readily detachable so as to allow the operator to exchange or clean the filter if a blockage occurs. In the case that the filter is detachable such a connection can be accomplished as mentioned previously via a permanent screw fixture attached to block  1 . The filter would require a complimentary fixture, such as a nut fixture, in order for it to be connected to block  1 . Another method of fixing the filter near or at inlet orifice  3  is to house the filter in a filter attachment which in turn can be attached to block  1  to assist facile assembly and disassembly of the filter. For example, the filter attachment could be made of a block of metal with dimensions which match the dimensions of block  1  and again essentially extend inlet orifice  3 . The filter attachment could then be attached to block  1  by one or more screws. The filter attachment in turn may also include additional features such as a permanent fixture, such as a screw fixture. Advantageously such a fixture essentially further extends inlet orifice  3  and allows the dispensing device for liquids to be connected to other equipment. 
     In another embodiment the dispensing device for liquids further comprises a lance which is situated near or at outlet orifice  4 . The lance can be connected to block  1  permanently or can be detachable from block  1 . In the case that the lance is detachable such a connection can be accomplished as mentioned previously via a permanent screw fixture attached to block  1 . The lance would require a complimentary fixture, such as a nut fixture, in order for it to be connected to block  1 . Lances are commonly used in agriculture to allow the operator to apply the agricultural liquid at a safe distance to himself. Lances are typically from about 80 to 120 cm in length. It is advantageous if the lance itself has a control valve at the tip of the lance (that is the end opposite to the side which is connected to block  1 ) to avoid run-off of the liquid. This additional feature ensures further improved operator safety and also increases the precision of the metering process.