[0001] The present invention is directed to a nozzle unit for the automatic injection of
a treatment fluid into a cavity, comprising a spray nozzle, a nozzle holder in which
the spray nozzle is secured, a pneumatic cylinder assembly having a cylinder device
defined by a cylindrical wall, and forward and rear cylinder end walls, and having
a piston device translatably disposed in the cylinder assembly and a piston rod whose
ends are fixedly secured respectively to the piston device and nozzle holder for translating
the latter in relation to the cylinder device, the piston device being arranged to
engage end-position senders adjacent at least one of the cylinder end walls, a bellows
device which encloses the piston rod and which is fixedly secured to the forward cylinder
end wall and the nozzle holder, means for feeding treatment fluid and means for feeding
gas under pressure to a mixing assembly in order to mix the fluid and the gas and
to expel the resulting mixture, means for feeding working gas to the cylinder assembly,
and a mount on the cylinder assembly for mounting the nozzle unit to a positioning
unit.
[0002] More particularly, the invention is directed towards a nozzle unit for various treatment
processes concerning cavities and the like in constructions which are to be surface
treated or filled with a fluid. The unit is especially intended for injecting rust
protectant into cavities and beams in vehicle chassis wherein their inner surfaces
are coated with a rust protecting oil, wax or similar, and is intended, together with
a plurality of similar nozzle units, to automatically treat a vehicle chassis on a
production line.
[0003] A nozzle unit of this sort is described in Swedish patent no. 8703858-4 (publication
no. 459 081). However, this prior art nozzle unit has a comparatively large number
of connecting hoses, which can hinder the unit in its operation and adjustment and
which are exposed to the risk of damage.
[0004] The object of the invention is to provide a nozzle unit having a minimal number of
externally located, stationary lines at a safe distance from the spray nozzle of the
unit.
[0005] A further object of the invention is to provide a nozzle unit with a comparativelely
simple construction, which is easy to clean and which lacks seals for the mixing assembly,
an advantage with aggressive fluids.
[0006] These objects are attained in accordance with the invention in a nozzle unit as defined
in the introductory passage, which is characterized in that the piston device and
the piston rod present through going, concentrically oriented bores, the piston rod
bore being aligned with the spray nozzle bore, a connecting nipple is disposed at
the rear cylinder end wall for feeding treatment fluid to a stock conduit fixedly
secured to this end wall and which is concentrically disposed in the cylinder assembly
and inserts into the piston device bore and the piston rod bore, and which, in the
projecting state of the nozzle unit, is arranged, together with a conduit means for
feeding mixing gas, to discharge at the inner end of the mixing assembly.
[0007] Further developments of the invention are apparent from the features indicated in
the subsidiary claims.
[0008] A preferred embodiment of the invention will now be described by way of example and
with reference to the accompanying drawings in which:
Fig. 1 depicts in side view a preferred embodiment of the invention;
Fig. 2 depicts in central longitudinal section the nozzle unit of Fig. 1;
Fig 3 depicts in enlarged scale the area around the forward cylinder end wall of the
nozzle unit and the discharge of the stock pipe; and
Fig. 4 illustrates a control circuit for the nozzle unit presented.
[0009] Referring initially to Figs. 1 and 2, the nozzle unit of the invention comprises
an interchangable spray nozzle 1 having a central bore 27, which is releasably secured
in a nozzle holder 2. The connecting end of the spray nozzle has a control peg with
which the spraying direction of the nozzle is adjusted by the peg being fitted into
a slot in the nozzle holder, which is schematically depicted in the right hand part
of Fig. 2. Reference numeral 3 generally indicates a pneumatic cylinder assembly which
is preferably of the Atlas Copco C 43 MD type with rotationally rigid piston rod 4.
In addition to the piston rod 4, the cylinder assembly 3 comprises a cylindrical wall
5 having attached forward and rear cylinder end walls, respectively 6 and 7. A piston
device 8 is arranged to reciprocate between the cylinder end walls and is equipped
with conventional seals. The piston device presents a through going, concentrically
arranged bore 9 in which the piston rod 4 is secured. The nozzle holder 2 is fixedly
secured to the end of the piston rod which projects from the cylinder assembly, for
example with a jam nut and a locking screw. A bellows device 10 protectively encloses
the projecting piston rod 4 and is conveniently secured adjacent the forward cylinder
end wall 6 and the nozzle holder 2.
[0010] Fig. 1 also depicts the nozzle unit signal valve 11, working valve 12 with its choke
valve 13 and stock valve 14 with its connecting nipple 16 for a treatment fluid (stock)
line. Reference numeral 17 indicates the associated control circuit which, together
with the above mentioned valves will be presented in more detail below and with reference
to Fig. 4.
[0011] Figs. 2 and 3 will now be referred to for a more detailed description of the internal
construction of the nozzle unit. The piston rod 4 which is shown in its completely
projecting state, presents a through going and concentrically arranged bore 18 and
19, the bore 18 in the projecting portion of the piston rod having a lesser internal
diameter than that of the bore 19 in the piston rod in the inserting portion of the
piston device. An intermediate portion 20 having a diameter varying in the longitudinal
direction from the bore 18 to the bore 19 and preferably, but not necessarily, of
conical form, communicates the bores with each other, see Fig. 3 in particular. Additionally,
a pneumatic, spray position signal sender 11, 26 is disposed in the forward cylinder
end wall 6, which will be described in more detail in connection with Fig. 4. An electric,
home position sender 29 is disposed in the rear end wall, which is schematically depicted
in Fig. 1. Aside from these end position senders, means 21 for feeding working gas
under pressure to the cylinder assembly 3, and for venting, are respectively arranged
for driving the piston device 8 and consequently the piston rod 4 forwards and backwards
in the cylinder assembly.
[0012] The stock valve 14 is fixedly linked with the rear cylinder end wall 7 and fixedly
supports a stock feed conduit 22 which is concentrically arranged in relation to the
cylindrical wall 5 and which discharges in the vicinity of the forward cylinder end
wall 6. The stock feed conduit 22 accordingly extends through the bore 9 in the piston
device 8 and into the bore 18-20 in the piston rod, the outer diameter of the stock
feed conduit being in all essential respects of similar size to the bore 18 in the
projecting portion of the piston rod, but being substantially smaller than the bore
19 in the inserting portion of the piston rod. The stock pipe 22 is slidably supported
in the various positions of the piston rod 8 between the rear cylinder end wall 7
and a short distance in front of the forward cylinder end wall, with a sealing fit
in the smaller bore 18 in which the stock conduit then discharges. However, in the
projected state of the nozzle unit, i.e. when the piston device 8 is in its forwardmost
position, as depicted in Figs. 2 and 3, the stock conduit 22 discharges into the intermediate
portion 20 of the through going bore in the piston rod 4 and allows the working gas
from the rear connection 21 to flow through the space (channel means) 23 between the
stock pipe 22 and the larger bore 19, through the bores 20 and 18 and out through
the bore 27 in the spray nozzle 1.
[0013] Finally, a mount 28 is disposed on the cylinder assembly 3 for mounting the nozzle
unit on or adjacent a mechanical positioning unit (not depicted), such as those of
the prior art in this technical field, see for example the above mentioned Swedish
patent no. 8703858-4 to which reference is made in this context. With the assistance
of the positioning unit, either a group of nozzle units is positioned in an exact
location relative to a vehicle chassis which is to be treated, or the chassis is positioned
in an exact location in relation to the group of nozzle units.
[0014] The nozzle unit of the present invention preferably works in the manner indicated
below.
[0015] After the nozzle unit and the cavity in the chassis which is to be treated therewith
have been made to assume an exact position in relation to each other, the spray cycle
is started with a pneumatic control signal 15 which is ceased when the predetermined
amount of stock has been sprayed into the cavity. This control may, for example, be
carried out with a program in a computer unit (not depicted). In the starting position,
however, the control signal is without pressure, which leads to the cylinder assembly
3 being subjected to pressure on the minus side (on the right hand side of the piston
device 8 in Fig. 2) and therefore also the piston device in the home position at the
rear cylinder end wall 7, which is detected by the electrical home position sender
29. When the control signal 15 is generated, it prompts the working valve 12 to change
position against the action of a compression spring (see Fig. 4 which depicts the
starting position for the nozzle unit), the working gas being allowed to flow from
the working gas feed line 24, through the valve 12 and the connection 21 in the rear
cylinder end wall 7, and into the plus side of the cylinder assembly 3 (to the left
of the piston device 8 in Fig. 2). At the same time, the minus side is vented through
the connection 21 in the forward cylinder end wall 6, the piston device 8 moving towards
the forward end wall and projecting the hollow piston rod 4 fixed to the piston device
therefrom, the spray nozzle 1 secured in the free end of the piston rod being inserted
into the cavity which is to be treated. The control signal also branches off to signal
valve 11, as is shown with the arrows 15 in Fig. 4.
[0016] When the piston device reaches its outer end position adjacent the forward cylinder
end wall 6, i.e. the position depicted in Figs. 2 and 3, the nozzle unit is in its
spray position and the piston device 8 acts on the operating means 26 of the forward
end position sender, which in turn shifts the signal valve 11 against the action of
a compression spring, wherein the control signal can pass through the signal valve
11 and be transmitted to the stock valve 14. However, if the spray nozzle 1 can not
be entirely projected into the cavity which is to be treated, for example due to missing
the spray opening, the signal valve will not be activated in this event and the stock
valve will not be acted on by any signal, thus providing automatic monitoring. The
control signals allowed through will, however, shift the stock valve 14 against the
action of a compression spring, wherein the treatment fluid is allowed to flow from
the treatment fluid feed line 25, through the stock conduit 22 and into the bore 18
in the piston rod 4 via its intermediate portion 20.
[0017] The sealing fit between the stock conduit 22 and the through going bore 18 in the
projecting portion of the piston rod leads to the stock conduit acting as a choke
for the working gas which is introduced through the rear cylinder end wall 7, so that
the piston device 8 is driven with full gas pressure from the starting position adjacent
the cylinder end wall 7 to a position shortly in front of the outermost position adjacent
the forward cylinder end wall 6, as depicted in Figs. 2 and 3, i.e. the spray position
of the nozzle unit. When the piston device has reached the spray position, the stock
conduit 22 discharges into the intermediate portion 20, which means that the working
gas can flow through the channel means 23 and into the bore 18. This construction
ensures that the piston device works at full pressure during the "plus movement",
i.e. shifting towards the spray position, and that the spray nozzle 1 obtains full
blowing gas pressure during the spray process.
[0018] When the stock valve 14 is opened, the treatment fluid is consequently fed through
the stock conduit 22 and sprays out within the through going bore 18, 20 in the piston
rod 4, where it is atomized and mixed with the working gas (the blowing air) from
the "plus side" of the cylinder assembly 3 (the side adjacent the rear cylinder end
wall 7). The mixture of blowing air and treatment fluid, which is mixed in the through
going bore 18, is thereafter sprayed out into the cavity in the chassis (above all
due to the pressure of the blowing gas) through the spray nozzle 1 which is secured
in the nozzle unit holder 2 on the end of the piston rod.
[0019] The working valve 12 is fed with working gas via a distributor block which distributes
working gas to several nozzle units in a group. The treatment stock which is to be
sprayed is fed from a common feed line 25, wherein the spray amount of stock is measured
with a geared meter (not depicted) which is common for the entire group. When the
pre-programmed amount has been applied, a magnetic valve (not depicted) ceases the
control signal 15. When the control signal disappears, this means that the stock valve
14 closes immediately. The signal to the working valve 12 is evacuated via choke valve
13 which maintains the valve 12 in the open position for 0.5 - 1. seconds after the
stock valve has closed. This subsequent blowing is carried out to blow the nozzle
clean from stock. When the working valve has returned to the initial position, the
air feed from the plus side of the cylinder swaps over to the minus side of the cylinder.
The piston device and the nozzle are then returned to the home position, which is
detected with the home position sender 29 in the rear cylinder end wall 7, which gives
a clear signal to the control system that the spray cycle has been completed.
[0020] Aside from oil and wax, the treatment fluid may be paint, powder material and similar.
The working gas is preferably air but may, if so desired, be any inert gas or gas
selected for compatibility with the treatment fluid. It is also possible, when necessary,
to swap the working gas for a fluid of some other sort than treatment fluid, for example
a liquid such as a diluent.
[0021] The advantages of the nozzle unit are over and above those apparent from the above,
in that prior art nozzle units have all the valves etc needed for operating the unit
centrally located in the plant and connected to the nozzle unit with hoses. In order
to operate a unit, at least four hoses are required, three for compressed air and
one for spray stock. Two of these hoses are movable at the nozzle unit. In accordance
with the invention, the valves have been shifted out to the cylinder - the air valve
for the working air and the stock valve. Now only two hoses are required. None are
movable. The stock is now sprayed out through the hollow piston rod of the cylinder,
and the position of the cylinder directly activates the opening of the stock valve,
which means simplifications in the control system which controls the process. Fewer
signals are needed for operation.
[0022] The invention is not limited to what has been described above and depicted on the
drawings, but rather may be altered within the scope of the patent claims.
1. A nozzle unit for the automatic injection of a treatment fluid into a cavity, comprising
a spray nozzle (1), a nozzle holder (2) in which the spray nozzle is secured, a pneumatic
cylinder assembly (3) having a cylinder device defined by a cylindrical wall (5),
and forward and rear (6, 7) cylinder end walls, and having a piston device (8) translatably
disposed in the cylinder assembly and a piston rod (4) whose ends are fixedly secured
respectively to the piston device and the nozzle holder for moving the latter in relation
to the cylinder device, the piston device being arranged to engage end-position senders
(26) adjacent at least one of the cylinder end walls (6), a bellows device (10) which
encloses the piston rod (4) and which is fixedly secured to the forward cylinder end
wall (6) and the nozzle holder (2), means (16, 22) for feeding treatment fluid and
means (21, 23) for feeding gas under pressure to a mixing assembly (18) in order to
mix the fluid and the gas and to expel the resulting mixture, means (12, 24) for feeding
working gas to the cylinder assembly (3), and a mount (28) on the cylinder assembly
for mounting the nozzle unit to a positioning unit characterized in that
the piston device (8) and the piston rod (4) present through going, concentrically
oriented bores (9, 18-20), the piston rod bore (18-20) being aligned with the bore
(27) in the spray nozzle (1), a connecting nipple (16) is disposed at the rear cylinder
end wall (7) for feeding treatment fluid to a stock conduit (22) fixedly secured to
this end wall and which is concentrically disposed in the cylinder assembly (3) and
inserts into the bores (9, 18-20) in the piston device (8) and the piston rod (4),
and which, in the projecting state of the nozzle unit, is arranged, together with
a channel means (23) for feeding mixing gas, to discharge at the inner end of the
mixing assembly (18).
2. A unit according to claim 1, characterized in that both the through going bore (9) in the piston device (8) and the through going bore
(19) in the inner end of the piston rod (4) present a larger internal diameter than
the external diameter of the stock pipe (22), whereby the space between the outer
diameter of the stock conduit and said through going bores form the channel means
(23) for feeding gas to the mixing assembly (18).
3. A unit according to claim 2, characterized in that the through going bore (18-20) in the piston rod presents a substantially conical
portion (20) which is located between said bores (18, 19) having different diameters
and which, in the projecting state of the nozzle unit, is located adjacent the discharge
of the stock conduit (22).
4. A unit according to claim 3, characterized in that the diameter of the bore in the piston rod having the lesser diameter (18) is substantially
similar to the external diameter of the stock conduit (22).
5. A unit according to any one of claims 1 to 4, characterized in that a connection (21) for the working gas of the cylinder assembly (3) is disposed adjacent
the rear cylinder end wall (7), and that in the projected state of the nozzle unit,
the gas from this connection, under pressure, is made to flow into the mixing assembly
(18) as mixing gas.
6. A unit according to any one of claims 1 to 5, characterized in that the bore in the piston rod (4) having the lesser diameter (18) serves as the mixing
assembly.
7. A unit according to any one of the preceding claims, characterized in that a connection (21) for the working gas of the cylinder assembly (3) is disposed adjacent
the respective cylinder end walls (6, 7), which connections are in communication with
a source of working gas (24) via a working valve device (12) which is controlled by
a control signal (15), that the end position sender (26) in the forward cylinder end
wall (6) is arranged to operate a signal valve (11) to feed, or alternatively to cease
said control signal (15) to a stock valve (14) which is disposed between the stock
conduit (22) and a source of treatment fluid (25), whereby the treatment fluid is
allowed to flow, or alternatively is prevented from flowing, into the stock conduit.
8. A unit according to claim 7, characterized in that a choke valve (13) is disposed in the control signal line system immediately adjacent
the working valve (12).
9. A unit according to any one of the preceding claims, characterized in that a flow meter is disposed in the stock supply line (25) to the unit and is connected
to a regulator unit which is arranged to provide the control signal (15).
10. A unit according to claim 10, characterized in that the regulator unit is in communication with a magnetic valve in the line system for
the control signal (15) respectively to allow through and to stop the control signal
to the working valve (12), and to the signal valve (11) and the stock valve (14).