US3866335A

US3866335A - Gas heated rotary drier

Info

Publication number: US3866335A
Application number: US379743A
Authority: US
Inventors: Richard E G Neville
Original assignee: AMF Inc
Current assignee: AMF Inc
Priority date: 1972-07-21
Filing date: 1973-07-16
Publication date: 1975-02-18
Anticipated expiration: 1992-02-18
Also published as: FR2194299A5; IT997957B; DE2337136A1; JPS4985654A; CA1000948A; BR7305529D0; GB1390396A

Abstract

A gas drier for tobacco and the like having a rotatable drum with internally disposed axially extending V-shaped vanes each open to the gas burners disposed along the bottom of the drier.

Description

United States Patent [1 1 Neville Feb. 18, 1975 I GAS HEATED ROTARY DRIER [75] Inventor: Richard E. G. Neville, Salisbury,

England [73] Assignee: AMF Incorporated, White Plains,

122 Filed: July 16, 1973 21 App1.No.;379,743

[30] Foreign Application Priority Data July 21,1972 Great Britain ..34291/72 US. Cl 34/133, 34/134,432/107 [51] lm. C1 F26b 11/02.

Field of Search 34/134, 133. 139; 432/107. 432/112; 165/89; 259/89, 90

[56] References Cited UNITED STATES PATENTS 2.348,6 73 5/1943 Degner 432 1;

be N e T L/l/l/Y/l/f 2,639,133 5/1953 Clary 432/113 FOREIGN PATENTS OR APPLICATIONS 10,744

Primary Examiner-Kenneth W. Sprague Assistant Examiner-Larry 1. Schwartz Attorney, Agent, or FirmGeorge W. Price; Charles J. Worth 57 ABSTRACT A gas drier for tobacco and the like having a rotatable drum with internally disposed axially extending V- shaped vanes each open to the gas burners disposed along the bottom of the drier.

8 Claims, 7 Drawing Figures Vl/I/l/l/i/jY/jA/ 5/1895 Great Britain 432/113 SHEET U 0F 4 1 GAS HEATED ROTARY DRIER This invention relates to driers for particulate or loose material such as rag or stem tobacco.

With the general availability of natural or propane gas, the gas drier is a relatively inexpensive and attractive alternative to the'steam drier for rag or stem drying. With a low thermal capacity and rapid response it is particularly suitable for automatic moisture control.

A known drier traditionally used for stem drying comprises a rotatably mounted cylinder having radially inwardly extending paddles. The cylinder is heated by strip type burners arranged below and parallel to the cylinder axis to throw flame at the cylinder along its entire length at the same moment. lts short paddles and high cylinder temperatures suit the low flow/high moisture removal stem application. The heat conduction along the paddles is negligible and size is based on the cylinder heating surface only.

For rag drying, larger paddles are required to match the larger volume flow. To keep the size and dwell time of the drier comparable to that of a steam drier for the same working temperatures (or smaller for higher working temperatures) the paddles must supply heat to the tobacco.

Conducting paddles are not practicable. Using the best practical conductor, copper, a 1 inch base triangular section only barely conducts sufficient heat; combined with an ne-half inch cylinder thickness the thermal capacity of the whole would be totally unacceptable. The conduction of steel is about'eight times worse and stainless 24 times worse. 1

According to the invention there is provided a rotary drier for particulate or loose material comprising a cyl-v inder arranged to rotate about its axis disposed horizontally or inclined to the horizontal and having formed along its cylindrical surface a plurality of hollow paddles extending axially along said cylinder and inwardly thereof. The interior of said paddles communicate with the exterior of the cylinder and at least one gas burner arranged below the cylinder to direct flame into the interior of the hollow paddles.

In the present drier the paddles are heated directly by gas flame, giving the maximum heat transfer and ensuring a high thermal efficiency. The paddles are preferably ofa V-shape or hollow triangular sections each with an open base exposed to the combustion space. If strip burners parallel to the cylinder axis are used there would be no room for the cooled gases in he paddle to escape, which would consequently prevent the flame entering the hollow paddle. The present construction avoids this problem by, in effect, dividing the normal strip type burner into short lengths which are inclined to the cylinder axis. Accordingly, at any one moment the flame only enters the paddle at the intersections of the open paddle base and the inclined burners. This arrangement allows the flame to enter the hollow paddle the detailed description which follows, taken together with the accompanying drawings wherein several embodiments of the invention are illustrated by way of example. It is to be expressly understood, however, that the drawings are for illustration purposes only and are not to be construed as defining the limits of the invention.

FIG. 1 is a side view of the rotary drier,

FIG. 2 is a view of the drier at the feed end thereof,

FIG. 3 is a view on the delivery end of the drier FIG. 4 is a section taken along the line 4-4 in FIG.

FIG. 5 is a plan view of the burners taken in the direction of the arrows 55 in FIG. 1,

FIG. 6 is a scrap view of an expansion follower for temperature measurement, and

FIG. 7 is a side view of a rotary drier which includes an air inlet probe for suppressing exhaust air ventilation.

Referring now to the drawings, a drier in accordance with the invention is provided with a chasis l0 comprising longitudinal side channels 11 supported on legs 12 and having cross channels 13. On the cross channels 13 are mounted pairs of support rollers 14, preferably of a reinforced phenolic resin which carry a cylinder 15 byway of

track rings

16 and 17 attached by spacers. The cylinder 15 is driven by belts 18 passing around a belt ring, formed as part ofthe track ring 16, and driven by a geared motor 19 or the like. The cylinder has its axis of rotation disposed at an angle of l% or 35? according to the desired flow rate and drying capacity. Generally, the inclination is preferably between 1 and 5. A thrust roller 20 is mounted on the cross channel 13 at the feed end for engagement with a rim 21 provided on the cylinder 15. A feed conveyor 47 which may be of the vibratory type is provided at one end of the drier with a discharge chute 55 being provided at the other end.

As is seen from FIG. 4, the cylinder 15 is formed with a series of inwardly projecting paddles 24 which are generally V-shaped or of an open base triangular cross section all extending axially off the cylinder. One side of each paddle 24 is positioned radially and the other obliquely relative to the rotation axis of the cylinder 15.

This is to insure that the radial sides of paddles 24 BURNER EQUIPMENT Normally forced draught ribbon type gas burners are fitted, with pilot burners, flame failure control and pneumatically operated-modulating valve giving a 20:1 turn down range. The burner assembly (see FIG. 5) is pivotably mounted on an axis adjacent and parallel to by leaving space either side of the scouring out of a chassis side member so that it can be swung down for cooled gases, and insures uniform heating of the cylinder throughout its length.

Further features of the presentinvention are cylinder temperature control by cylinder expansion measurement, or differential or zonal cylinder temperature control by thermistor, and combined casing cooler and airaccess to the burners. Heating by diagonal strip burners has the following advantages compared with other known methods, viz.

I. It is simple and avoids the use of a fan found in other driers which has to handle very hot gasses, 2. The cylinder and especially its open paddles can be uniformly heated from end to end, or 3. The cylinder and especially its open paddles can be heated differentially to reduce the overdried tobacco at start-up and shut-down and to give quick response control during normal running,

4. Direct flame exposure of the open paddles gives a more efficient heat transfer from gas to cylinder.

The hot combustion gases are kept in close proximity to the cylinder by a cylindrical combustion space casing 27, (see FIG. 4) which is concentric with the cylinder l5 and surrounds it at a few inches distance. The bottom of the casing'27 is open for the burners 28 and the top includes a tapered flue gas collection manifold 29 which connects to a flue duct 30.

A few inches outside the combustion space casing 27 are two further concentric

curved sheets

31 and 32, one on each side of the cylinder 15, forming a narrow curved air passage way. The passage way finishes either side of the flue manifold where a thin slot 33 connects with the corner space 35 formed by the outer insulation boards 34.

Both corner spaces 35 are connected to a fan 36 (see FIG. 1) which enables air to be drawn up through the curved passage way, heated and delivered to the cylinder via a ducting 37. Ambient air is drawn in through an adjustable entry 39. This method of pre-heating the cylinder drying air has the double purpose of improving the overall thermal efficiency of the drier and considerably reducing the heat conducted to the outer insulation. As a result the outside surface of the insulation is below 100F. and typically only 20F. above ambient. The outer casing is of conventional asbestos board construction.

Alternatively, where pre-heating of the drying air is not required, the corner spaces are connected to the combustion gas flue 29 and a flow of casing cooling air induced by convection.

EXHAUST AIR For high duty application the drying air is contra flow and the cylinder is provided with a cylindrical feed end sieve 40 as an extension of the cylinder 15, and a sieve cleaner 41. Contra flow is essential for applications with high input moisture content where the exhaust air I is saturated. Additional air is fed via fan inlet 57 to the feed hood from a pre-heater in such applications to prevent condensation.

For lesser duties a lower volume air flow is used without a sieve.

Proposed Range of sizes Cylinder diameter in feet 3 4 Number of paddles 4 8 cylinder rotational 8 speed in r.p.m.

Maximum rag flow rate at:

3% cylinder inclination in lb/hr 5.000 10.000 20,000 F34" cylinder inclination in lb/hr 2.500 5.000 l0,000

Heated cylinder lengths in feet: 8

l2 l2 l6 l6 I6 20 20 24 directed toward the working radial surfaces of the paddles 24.

This direct heating of the paddles 24 permits a thin cylinder and paddle wall to be used, giving a lower thermal capacity than the corresponding size of steam drier. Typical heating and cooling rates for a oneeighth inch thick cylinder being 50F/min under normal working conditions. At 15 r.p.m. this is a fluctuation of only 3VaF per revolution.

CYLINDER TEMPERATURE CONTROL The traditional gas control from the cylinder exhaust air temperature is not satisfactory for use with automatic moisture control system or for good manual control. The exhaust air temperature is only a poor reflection of the cylinder temperature as it is effected by exhaust air flow, tobacco temperature and moisture removal and it furthermore lags behind the cylinder temperature.

For manual control and the simpler automatic control systems, the gas drier of the present invention is fitted with average cylinder temperature control by measurement of cylinder expansion using followers 42 (see FIG. 6) on one but preferably on both runner track rings 16 (not shown) and 17. The position of a follower 42 is converted by a transducer 43 into van electric signal and the difference between the signals from the transducers 43, after smoothing, gives a measure of cylinder expansion and hence cylinder temperature.

The resulting signal is fed to a temperature indicating process controller (not shown) which controls a modulating valve 44 in the gas supply to maintain a set temperature. With automatic moisture control the set point of the temperature is adjusted automatically by cascade control.

THE CYLINDER TEMPERATURE IS SET MANUALLY The virtually instantaneous reaction to cylinder temperature results in a very tight control of cylinder temperature. The burners are sized to give double the normal working heat. This, combined with the low thermal capacity of the cylinder, enables the cylinder tempera ture to be increased or reduced rapidly and accurately within the normal working range of l50to 400F.

An over-riding safety control is fitted based on the conventional exhaust air temperature measurement.

ZONAL CYLINDER TEMPERATURE CONTROL For applications with fully automatic feed forward and feed back control from moisture meters with automatic start-up and shut down the burner 28 is divided into two or more sections (see FIG. 5) depending on the length of the drier. Each section has an independent gas control valve (not shown).

The temperature of each zone of the drier corresponding to each burner section is measured by a number of thermistors 56 (of which only one is shown in FIG. 1) fixed to the cylinder surface and connected in parallel to give an average temperature for each zone.

This replaces the overall cylinder expansion measure-.

ment used for manual and simpler automatic control systems.

One side of each thermistor is connected to the cylinder and connection is made to the rotating cylinder by a sprung metal roller on the track ring.

The other connection from the thermistors in each zone is brought to a slip ring mounted on an insulated extension of the track ring. Thermistors are used for the temperature measurement as their very high resistance change with temperature makes them insensitive to variation in slip ring resistance. Instead of arranging slip rings on the outside of the cylinder the connections may extend to one end of the cylinder where longitudinally extending arms are provided with a connected arm diametrically positioned, at the centre of which arm is mounted a slip ring of considerably less diameter than that of the cylinder. Since a small diameter slip ring can be used in such a construction a proprietory slip ring and brush enclosed in a dustproof housing can be used.

A separate temperature controller for each zone enables the temperature of each zone to be controlled independently of its neighbor. This zonal or differental temperature control is used at start up and shut down and also during normal running.

At start up as the tobacco runs in from the infeed 47 to the discharge 55, the down stream zones are heated up successively after the upstream zones using a programmed start. Similarly at shut down as the tobacco runs out the upstream zones are turned off successively before the down stream zones. This avoids over-dried tobacco during run-in and run-out.

During normal working the feed end zone only is used to control short term variations in output moisture control and the delivery end zone is correct short term output variations in mositure content. This is achieved by a system of duel control which ensures that short term fluctuations are corrected by the appropriate end zones and long term variations are corrected by the general temperature level of all zones.

This arrangement of zonal cylinder temperature control enables quick response corrections to be made which are not possible with a cylinderofa uniform temperature throughout its length. The Paddles are divided between zones to allow for any differential expansion.

To improve the ability of the tobacco to fill cigarettes using a minimum amount of tobacco, it is often required to stew the tobacco in the drier, i.e., suppress the exhaust air ventilation and raise the tobacco'to around 170F. The heat for drying is supplied by the drier and though the majority of the moisture removal still takes place in the drier, a greater proportion is removed in the cooler by evaporative cooling.

A weakness of this method of operation is the uneven moisture loss that can occur at this high temperature both between the drier and cooler and in the cooler. To overcome this there is provided a pre-heated air inlet probe 45 as shown in FIG. 7.

This probe 45 is introduced at the delivery end of the drier and discharges air via an air diffuser 46 about one-third of the heat length from the delivery end. The feed-end of the cylinder is carefully sealed and the tunnel of the vibrating feed conveyor 47 is sealed by a succession of curtain seals (not shown). A small controlled amount of air (approximately 250 c.f.m. in a 4 ft. diameter drier) is exhausted from the feed hood. Adjustment of this air flow determines the temperature achieved by the tobacco in'the first two-thirds of the cylinder heated length. The tobacco temperature at this point is sensed by a thermistor 48 attached to the end of the probe and so arranged that it is always covered with a fresh fall of tobacco.

The majority of the air (approximately 1,250 c.f.m. in a 4 ft. diameter drier) is exhausted from the deliver end hood so that the ventilation which takes place in the last one-third of the cylinder heated length cools the tobacco to normal drier outlet temperature of around l00/120F.

The air inlet probe 45 is cantilevered from the delivery end and arranged to rotate to keep it clear of falling tobacco. The probe is rotated through a shaft 49 driven by a motor 50. The hot air from the curved air space and the slots 33 is fed to the probe by a fan 51 and ducting 52. Ambient air enters through an adjustable entry 53. The thermistor connections are brought out via a small slip ring (not shown). The air diffuser has sufficient pressure drop across it to prevent tobacco settling on it.

The drying capacity of the first two-thirds of the drier length is reduced due to the suppressed ventilation. In a 4' dia. X 16 heated length cylinder of the kind (shown in FIG. 7) up to 5 percent moisture from 5,000 lbs/hr. of rag can be removed. This removal figure includes the removal in the cooler, the heat for which is supplied in the drier.

Although several embodiments of the invention have been illustrated and described in detail, it is to be expressly understood that the invention is not limited thereto. Various changes may be made in the design and arrangement of the parts without departing from the spirit and scope of the invention as the same will now be understood by those skilled in the art.

I claim:

1. A rotary drier for, particulate or loose material comprising a cylinder arranged to rotate about its axis inclined to the horizontal, said cylinder having formed along its cylindrical surface a plurality of hollow paddles extending axially along said cylinder and inwardly thereof, said paddles being V-shaped in cross section with one side of each paddle being disposed radially and the other side being disposed obliquely thereto, the interior of said paddles communicating with the exterior of the cylinder andat least one gas burner arranged below the cylinder to direct flame into the interior of the hollow paddles.

2. A rotary drier as claimed in claim 1 in which said burner comprises a plurality of strip burners which are provided positioned obliquely with respect to the cylinder axis.

3. A rotary drier as claimed in claim 1 in which said cylinder is surrounded along its length by a cylindrical wall defining a combustion space between said cylinder and said wall, the interior of said paddles communicating with said combustion space, and the bottom of the combustion space being open to said burner.

4. A rotary drier as claimed in claim 3 in which the top of the combustion space includes a tapered flue gas collection manifold which communicates with a flue duct for removing waste combustion gases.

5. A rotary drier as claimed in claim 4 further including means for introducing air into said cylinder, said means comprising a passage way for conducting ambient air around said cylinder to preheat the air and for separating the ambient air from combustion gases, a fan for drawing air through said passage way and ducting for passing the preheated air to the interior of said cylinder.

6. A rotary drier as claimed in claim further including an inlet probe for introducing pre-heated air into said cylinder at a position intermediate its ends.

7. A rotary drier for particulate or loose material comprising a cylinder arranged to rotate about its axis inclined to the horizontal, said cylinder having formed along its cylindrical surface a plurality of hollow paddles extending axially along said cylinder and inwardly thereof, the interior of said paddles communicating with the exterior of the cylinder, at least one gas burner arranged below the cylinder to direct flame into the interior of the hollow paddles, said cylinder being surrounded along its length by a cylindrical wall defining a combustion space between said cylinder and said wall communicating with the interior of said paddles and the bottom thereof being open to said burner, the top of the combustion space including a tapered flue gas collection manifold which communicates with a flue duct for removing waste combustion gases, and means for introducing air into said cylinder, said means com prising a passageway for conducting ambient air around said cylinder to preheat the air and for separating the ambient air from combustion gases, a fan for drawing air through said passageway and ducting for the preheated air to the interior of said cylinder.

8. A rotary drier as claimed in claim 7 further including an inlet probe for introducing pre-heated air into said cylinder at a position intermediate its ends.

Claims

1. A rotary drier for particulate or loose material comprising a cylinder arranged to rotate about its axis inclined to the horizontal, said cylinder having formed along its cylindrical surface a plurality of hollow paddles extending axially along said cylinder and inwardly thereof, said paddles being V-shaped in cross section with one side of each paddle being disposed radially and the other side being disposed obliquely thereto, the interior of said paddles communicating with the exterior of the cylinder and at least one gas burner arranged below the cylinder to direct flame into the interior of the hollow paddles.

6. A rotary drier as claimed in claim 5 further including an inlet probe for introducing pre-heated air into said cylinder at a position intermediate its ends.

7. A rotary drier for particulate or loose material comprising a cylinder arranged to rotate about its axis inclined to the horizontal, said cylinder having formed along its cylindrical surface a plurality of hollow paddles extending axially along said cylinder and inwardly thereof, the interior of said paddles communicating with the exterior of the cylinder, at least one gas burner arranged below the cylinder to direct flame into the interior of the hollow paddles, said cylinder being surrounded along its length by a cylindrical wall defining a combustion space between said cylinder and said wall communicating with the interior of said paddles and the bottom thereof being open to said burner, the top of the combustion space including a tapered flue gas collection manifold which communicates with a flue duct for removing waste combustion gases, and means for introducing air into said cylinder, said means comprising a passageway for conducting ambient air around said cylinder to preheat the air and for separating the ambient air from combustion gases, a fan for drawing air through said passageway and ducting for the preheated air to the interior of said cylinder.