CN109501356A - Water plant dewatering system - Google Patents

Abstract

The present invention provides water plant dewatering system, including squeezer, squeezer includes squeezing casing, two spirals being mounted in squeezing casing, the power device being connected with spiral, and it is mounted on the sieve in squeezing casing, it squeezes casing and is equipped with feed inlet, water outlet, and slag notch, sieve is located at the periphery of spiral, spiral includes helical axis and multiple helical blades being mounted on helical axis, and there is top clearance in each spiral between two neighboring helical blade, the helical blade of one spiral stretches in the top clearance between the two neighboring helical blade of another spiral.Two spirals can generate stronger squeezing action to water plant in rotary course in the present invention, and water plant is more fully dehydrated, to guarantee that the water separation capability of this squeezer and water plant dewatering system is stronger.

Description

Water plant dewatering system

Technical field

The present invention relates to a kind of dehydration equipments, more particularly to a kind of water plant dewatering system.

Background technique

Water hyacinth also known as Eichhornia crassipes are the herbaceous plant that swims, usually 30-60 centimetres high.The fibrous root of water hyacinth is flourishing, and In brownish black, up to 30 centimetres.Water hyacinth fertility is extremely strong, and under optimum conditions, there are about 130,000 for the water hyacinth of 1 hectare of water surface Strain.So high density and increment, when spreading unchecked, meeting Severe blockage navigation channel, influences water transport, also obstruction water flow, influences flooding period Between flood discharge；And meeting polluted-water, influence the yield and quality of aquatic products；And then destroy the balance of Ecology.

In recent years, the lasting enhancing of water hyacinth pollution in some rivers, and have the characteristics that the time is early, the period is long, daily beat Up to 2000 tons of fishing.But the existing collection mode to water plant has following defects that operation ship function is simple, only simply The water surface salvages function, and cannot store a large amount of water hyacinth, must thus configure large-tonnage cargo ship and assist storage and transhipment； Since water hyacinth water content is high and volume is big, existing cargo ship has actually transported a large amount of water when transporting water hyacinth, and Water hyacinth volume is big, specific gravity is small, causes ship charging ratio low, and causes effective Transport Rate low, and then causes operating cost big Big raising, entire process operation is very uneconomical, and the subsequent harmless treatment to water hyacinth, turn waste into wealth using unfavorable. Therefore, it is necessary to which it is excellent to carry out to the water plant salvaged to increase related optimization equipment using more scientific disposal options Change disposition.

Especially annual autumn will generally enter the seasonal water plant large area outbreak period such as water hyacinth, serious prestige Coerce urban river water Environmental Health.Water hyacinth pollutes the characteristics of showing " appearance is early, conversion is fast, continues by force ".And water hyacinth is aqueous Amount is very high, and up to 92%~95% or so, light specific gravity causes the shipment rate of collecting ship low, and freight is high, uneconomical, to water calabash The disposal site floor area requirement of Lu Houxu innoxious use is big.And after water hyacinth corruption, sewage is more, matches needed for existing disposition factory The sewage disposal system capacity set need to be increased sharply, and sewage disposal is costly.Meanwhile water hyacinth itself has utility value；Its Nutriments and the various trace elements such as crude protein rich in, crude fat, amino acid, carrotene, general flavone, are great The species of potentiality to be exploited.But due to moisture content height, volume is big, causes difficulty to the disposition of subsequent new process, therefore to water hyacinth Preconditioning technique it is particularly important, especially develop it is a kind of can be to the equipment that the water plants such as water hyacinth are carried out dehydrating just It is particularly important.

Summary of the invention

In view of the foregoing deficiencies of prior art, the technical problem to be solved in the present invention is that providing a kind of water separation capability Strong water plant dewatering system.

To achieve the above object, the present invention provides a kind of water plant dewatering system, including squeezer, the squeezer packet It includes squeezing casing, two spirals being mounted in squeezing casing, the power device being connected with spiral and is mounted on squeezing casing In sieve, the squeezing casing be equipped with feed inlet, water outlet and slag notch, the sieve is located at the periphery of spiral, described Spiral includes helical axis and multiple helical blades being mounted on helical axis, and in each spiral between two neighboring helical blade With top clearance, the helical blade of a spiral is stretched between the extruding between the two neighboring helical blade of another spiral In gap.

Further, the sieve is cylindrical in shape, and the sieve is looped around the periphery of two spirals.

Further, multiple resistance teeth are installed, and whole resistance teeth are distributed along the axially spaced-apart of spiral on the sieve.

Further, the spiral includes feeding screw section, the precompressed that edge is sequentially distributed by feed inlet to slag notch direction Contracting section and self-built pressure section, the helical axis includes feeding section split axle in the feeding screw section, pre- in precommpression section Compression section split axle and the self-built pressure section split axle in self-built pressure section, pacify on the feeding section split axle and precommpression section split axle Equipped with multiple helical blades.

Further, the screw pitch of the precommpression section is gradually reduced by feed inlet to slag notch direction.

Further, back pressure ring is installed on the self-built pressure section split axle.

Further, spiral one end corresponding with feed inlet is lower than spiral one end corresponding with slag notch.

Further, the water plant dewatering system, further includes feed conveying device, and the feed conveying device goes out Material end is located at the top of the feed inlet of squeezer.

Further, the feed conveying device is weighing belt.

Further, the water plant dewatering system further includes material conveying device out, it is described go out material conveying device into Material end is located at the lower section of the slag notch of squeezer.

As described above, water plant dewatering system of the present invention, has the advantages that

The working principle of water plant dewatering system in the present invention are as follows: water plant is put into squeezing casing by feed inlet In, power device drives spiral rotating, and it is mobile to slag notch direction that spiral drives water plant, and to aquatic in moving process Plant generates squeezing action, so that the moisture in water plant is detached, and the moisture deviate from is by sieve and by being discharged Mouth outflow, water plant are discharged after being dehydrated by slag notch；Simultaneously as spiral there are two being installed in this squeezing casing, and one The helical blade of a spiral stretches in the top clearance between the two neighboring helical blade of another spiral, so that two spiral shells Stronger squeezing action can be generated to water plant by being spun in rotary course, and water plant is more fully taken off Water, to guarantee that the water separation capability of this squeezer and water plant dewatering system is stronger.

Detailed description of the invention

Fig. 1 is the structural schematic diagram of water plant dewatering system in the present invention.

Fig. 2 is the top view of water plant dewatering system in the present invention.

Fig. 3 is the structural schematic diagram of squeezer in the present invention.

Fig. 4 is the relative positional relationship schematic diagram of two spirals in the present invention.

Fig. 5 is mounting structure schematic diagram of two spirals in squeezing casing in the present invention.

Fig. 6 is the left view of squeezer in the present invention.

Fig. 7 is the structural schematic diagram that casing is squeezed in the present invention.

Fig. 8 is the top view of squeezer in the present invention.

Fig. 9 is the attachment structure schematic diagram of power device and spiral in the present invention.

Figure 10 is the relative positional relationship schematic diagram of sieve and two spirals in the present invention.

Figure 11 is the structural schematic diagram of power device in the present invention.

Component label instructions

1 squeezer, 124 feeding screw section

11 squeezing 125 precommpression sections of casing

The self-built pressure section of 111 feed inlet 126

112 water outlet, 127 back pressure ring

113 slag notch, 128 compaction cavum

114 effluent collection bucket, 13 power device

12 spiral, 14 sieve

121 helical axis, 15 resistance tooth

1211 feeding section split axles 16 squeeze rack

1212 precommpression section split axle, 2 feed conveying device

1213 self-built pressure section split axles 3 go out material conveying device

122 helical blades 4 clear up platform

123 top clearances

Specific embodiment

Embodiments of the present invention are illustrated by particular specific embodiment below, those skilled in the art can be by this explanation Content disclosed by book is understood other advantages and efficacy of the present invention easily.

It should be clear that structure depicted in this specification attached drawing, ratio, size etc., only to cooperate specification revealed Content is not intended to limit the invention enforceable qualifications, therefore does not have so that those skilled in the art understands and reads Technical essential meaning, the modification of any structure, the change of proportionate relationship or the adjustment of size are not influencing institute's energy of the present invention Under the effect of generation and the purpose that can reach, the range that disclosed technology contents can be covered should all be still fallen in It is interior.Meanwhile cited such as "upper", "lower", "left", "right", " centre " and " one " term in this specification, it is merely convenient to Narration is illustrated, rather than to limit the scope of the invention, relativeness is altered or modified, and is changing skill without essence It is held in art, when being also considered as the enforceable scope of the present invention.

As shown in Figure 1 to 11, the present invention provides a kind of water plant dewatering system, including squeezer 1, and squeezer 1 wraps Include the spiral 12 that squeezing casing 11, two is mounted in squeezing casing 11, the power device 13 and installation that are connected with spiral 12 Sieve 14 in squeezing casing 11, squeezing casing 11 are equipped with feed inlet 111, water outlet 112 and slag notch 113, sieve 14 Positioned at the periphery of spiral 12, spiral 12 includes helical axis 121 and multiple helical blades 122 being mounted on helical axis 121, and every There is top clearance 123, the helical blade 122 of a spiral 12 protrudes into a spiral 12 between two neighboring helical blade 122 Into the top clearance 123 between the two neighboring helical blade 122 of another spiral 12.Water plant dehydration system in the present invention The working principle of system are as follows: be put into water plant in squeezing casing 11 by feed inlet 111, power device 13 drives spiral 12 to revolve Turn, it is mobile to 113 direction of slag notch that spiral 12 drives water plant, and generates to squeeze to water plant in moving process and make With so that the moisture in water plant is detached, and the moisture deviate from passes through sieve 14 and flowed out by water outlet 112, water Plant is discharged after being dehydrated by slag notch 113；Simultaneously as spiral 12 there are two being installed in this squeezing casing 11, and one The helical blade 122 of spiral 12 stretches to the top clearance 123 between the two neighboring helical blade 122 of another spiral 12 In, so that two spirals 12 can generate stronger squeezing action to water plant in rotary course, and enable water plant It is more fully dehydrated, to guarantee that the water separation capability of this squeezer 1 and water plant dewatering system is stronger.

As shown in Figure 10, sieve 14 is cylindrical in shape in the present embodiment, and sieve 14 is looped around the periphery of two spirals 12.Spiral 12 Spiral helicine channel is formed between sieve 14.In 12 rotary course of spiral, spiral 12 drives water plant along the helical form Channel it is mobile, and water plant will receive the helical blade 122 of spiral 12 and the squeezing action of sieve 14, thus by aquatic plant Water in object squeezes out, and is flow at water outlet 112 by the mesh on sieve 14, then is discharged by water outlet 112.Meanwhile such as Shown in Fig. 3, multiple resistance teeth 15 are installed, and whole resistance teeth 15 are along the axially spaced-apart of spiral 12 in the present embodiment on sieve 14 Distribution.During spiral 12 and sieve 14 squeeze water plant, sieve 14 will receive the reaction force expanded outwardly, so that sieve Net 14 can expand outwardly and generate deformation, and above-mentioned resistance tooth 15 can apply its generation deformation of prevention to sieve 14 in the present embodiment Power, so that sieve 14 be avoided to generate larger deformation, be even damaged, and guarantee that sieve 14 is able to cooperate spiral 12 persistently to aquatic Plant applies extruding force.Resistance tooth 15 is annular in shape in the present embodiment, and is set in the outside of sieve 14.

As shown in figure 5, spiral 12 includes that edge is sequentially distributed by feed inlet 111 to 113 direction of slag notch in the present embodiment Feeding screw section 124, precommpression section 125 and self-built pressure section 126, helical axis 121 include sending in feeding screw section 124 Expect section split axle 1211, the precommpression section split axle 1212 in precommpression section 125 and the self-built pressure in self-built pressure section 126 Section split axle 1213, is mounted on multiple above-mentioned helical blades 122 on feeding section split axle 1211 and precommpression section split axle 1212.This reality It applies spiral 12 in example to be constituted by above-mentioned three sections, respectively feeding screw section 124, precommpression section 125 and self-built pressure section 126.Together When, feeding section split axle 1211 and precommpression section 125 are equipped with above-mentioned helical blade 122.Feeding screw section 124 in the present embodiment Screw pitch remains unchanged.As shown in figure 5, the screw pitch of precommpression section 125 is by feed inlet 111 to 113 direction of slag notch in the present embodiment It is gradually reduced, i.e., spiral 12 is designed in its precommpression section 125 using the structure of varying pitch, and the screw pitch edge of the precommpression section 125 Water plant moving direction is gradually reduced, so that the space size in this section of upper spiral helicine channel is gradually reduced, so that water Plant in moving process of channel, will receive increasing extruding force along this, and guarantee the water in water plant Divide sufficiently to squeeze out and, realization is adequately dehydrated water plant.The above-mentioned not set above-mentioned helical blade 122 of self-built pressure section 126. As shown in figure 5, back pressure ring 127 is installed on self-built pressure section split axle 1213 in the present embodiment, back pressure ring 127 and precommpression section 125 Helical blade 122 between have compaction cavum 128.When water plant is moved to the compaction cavum 128, can further it be pressed Contracting, and the discharge of slag notch 113 can be passed through.Self-built pressure section 126 has self-built extrusion pressure-off treatment function in the present embodiment. The spacing of above-mentioned two neighboring resistance tooth 15 is equal with the screw pitch of corresponding precommpression section 125 in the present embodiment.Above-mentioned precompressed The screw pitch of contracting section 125 is gradually reduced by feed inlet 111 to 113 direction of slag notch, the spacing of two neighboring resistance tooth 15 also by into Material mouth 111 to 113 direction of slag notch is gradually reduced.Resistance tooth 15 is realized by the variation of spacing and is located at spiral shell at precommpression section 125 The space for revolving the channel of shape gradually becomes smaller, and completes the extruding to water plant.The spiral of above-mentioned sieve 14 and precommpression section 125 The gradually smaller spiral helicine channel in space is formed between blade 122.

As shown in Figure 1, the one end corresponding with feed inlet 111 of spiral 12 is lower than spiral 12 and slag notch in the present embodiment 113 corresponding one end.The diagonally upper direction inclination of spiral 12 in the present embodiment.Water plant is entered by feed inlet 111 to be squeezed After machine 1, to slag notch 113 and moved up in the case where the extruding of spiral 12, push are acted on, in the process, from water plant The moisture of abjection can flow downward under the effect of gravity, so as to be sufficiently disengaged from water plant.

As shown in Figure 1, water plant dewatering system in the present embodiment, further includes feed conveying device 2, feed conveying device 2 discharge end is located at the top of the feed inlet 111 of squeezer 1.During the dehydration process, water plant is defeated through feed conveying device 2 It send to its discharge end, and falls into the feed inlet 111 of squeezer 1, and then realized using squeezer 1 and water plant is dehydrated.This reality It applies example and water plant is delivered in squeezer 1 using feed conveying device 2, effectively increase this water plant dewatering system Dehydration efficiency.Meanwhile feed conveying device 2 is weighing belt in the present embodiment, which can not only be delivered to water plant It in squeezer 1, and can weigh to water plant, and can continuously record water plant charging situation, be carried out for subsequent technique Data collection task.The driving method of weighing belt uses automatically controlled driving in the present embodiment.

As depicted in figs. 1 and 2, water plant dewatering system in the present embodiment further includes that material conveying device 3, discharging out are defeated The lower section for sending the feed end of device 3 to be located at the slag notch 113 of squeezer 1.Discharging is fallen in by the water plant that slag notch 113 is discharged In conveying device 3, and it is delivered to setting position by going out material conveying device 3, avoids after being dehydrated water plant at slag notch 113 Accumulation, and influence subsequent deslagging.Going out material conveying device 3 in the present embodiment is telescopic belt machine.

Squeezer 1 has above-mentioned two spiral 12 in the present embodiment, and there are two above-mentioned spiral helicine logical for tool in squeezer 1 Road.Two spiral helicine channels are communicated with slag notch 113.Slag notch 113 is larger in the present embodiment, is conducive to the outer of impurity Row, so that 1 passability of this squeezer is stronger, and can handle the water plant containing certain impurity.The spiral shell of spiral 12 in the present embodiment Away from larger.

Above-mentioned squeezer 1 is also referred to as double helix exrusion dewaterer in the present embodiment.Squeezer 1 and dehydration system in the present embodiment System, is fed, production capacity is big simultaneously using above-mentioned double helix.And in squeezer 1 in each spiral 12 two neighboring helical blade 122 it Between there is top clearance 123, the helical blade 122 of a spiral 12 stretches to the two neighboring helical blade of another spiral 12 In top clearance 123 between 122, i.e., two 12 cross-distributions of spiral in squeezer 1, in squeezer 1 in two spirals 12 For the heart away from the sum of the radius less than two spirals 12, so that 1 overall volume of squeezer is small, occupied area is small, low in energy consumption.The present embodiment Middle squeezer 1 is that effectively, dehydration rate meets design requirement, and it is vertical that equipment capacity substantially meets setting 13 using screw press technique Square m/min of requirement.Meanwhile double helix uses cross-distribution in the present embodiment, the bridge formation that can effectively prevent large quantities of chargings is existing As, while can also reduce charging storage capacity, that is, reduce the volume of squeezing casing 11.The use of this squeezer 1 is above-mentioned step by step, multistage becomes Away from and back pressure ring 127 structure design, have dehydration rate high, crushing efficiency is high, and supplied materials is adaptable, can handle thin branch, bubble The low-intensity material such as foam box, plastic bottle.Above-mentioned power device 13 is motor in the present embodiment, easy to control, is set convenient for same front end Standby linkage control, and motor driven is used, mechanical property is hard, and anti-overload capacity is strong, is better than hydraulic system software feature.The present embodiment The compression ratio of middle squeezer 1 and dewatering system is big.

Above-mentioned squeezing casing 11 is mounted in squeezing rack 16 in the present embodiment.And above-mentioned squeezing casing 11 includes that water outlet is received Collection bucket 114, above-mentioned water outlet 112 is located at the lower end of effluent collection bucket 114.Water plant dewatering system further includes in the present embodiment Cleaning platform 4 positioned at 1 side of squeezer, when needed, service personnel are stood on the cleaning platform 4 convenient for squeezer 1 Inside cleared up.

Above-mentioned water plant is specially water hyacinth in the present embodiment.Dewatering system is mainly used for water hyacinth in the present embodiment It is carried out dehydrating.Dewatering system in the present embodiment weighs to water hyacinth using above-mentioned weighing belt, and accurate perception sheet is de- The amount of water hyacinth handled by water system can continuously record water hyacinth charging feelings so that this dewatering system has real-time function of weighing Condition carries out data collection task for subsequent technique.Above-mentioned squeezer 1 is designed using the structure of double helix in the present embodiment, and two A 12 cross-distribution of spiral, varying pitch step by step, and 12 tail portion of spiral can be carried out self-built extrusion press-dehydrating disposing technique.This dehydration system System has processing capacity, and broken, volume reduction, dehydration efficiency are high greatly, to water plant, can handle the aquatic plant for accommodating certain impurity Object lays the foundation for subsequent technique disposition.The discharging section of this dewatering system, to by slag notch 113 be discharged water plant residue, It is exported using belt feeder to follow-up equipment, and squeeze water is using direct emission after Simple filter dilution.

In conclusion the present invention effectively overcomes various shortcoming in the prior art and has high industrial utilization value.

The above-described embodiments merely illustrate the principles and effects of the present invention, and is not intended to limit the present invention.It is any ripe The personage for knowing this technology all without departing from the spirit and scope of the present invention, carries out modifications and changes to above-described embodiment.Cause This, institute is complete without departing from the spirit and technical ideas disclosed in the present invention by those of ordinary skill in the art such as At all equivalent modifications or change, should be covered by the claims of the present invention.

Claims (10)

1. a kind of water plant dewatering system, it is characterised in that: including squeezer (1), the squeezer (1) includes squeezing casing (11), two spirals (12) being mounted in squeezing casing (11), the power device (13) being connected with spiral (12) and installation Sieve (14) in squeezing casing (11), the squeezing casing (11) are equipped with feed inlet (111), water outlet (112) and go out Cinder notch (113), the sieve (14) are located at the periphery of spiral (12), and the spiral (12) includes helical axis (121) and multiple peaces Helical blade (122) on helical axis (121), and have between two neighboring helical blade (122) in each spiral (12) Have top clearance (123), the helical blade (122) of a spiral (12) stretches to the two neighboring spiral of another spiral (12) In top clearance (123) between blade (122).

2. water plant dewatering system according to claim 1, it is characterised in that: the sieve (14) is cylindrical in shape, the sieve Net (14) is looped around the periphery of two spirals (12).

3. water plant dewatering system according to claim 1, it is characterised in that: be equipped with multiple resistances on the sieve (14) Power tooth (15), and whole resistance teeth (15) are distributed along the axially spaced-apart of spiral (12).

4. water plant dewatering system according to claim 1, it is characterised in that: the spiral (12) includes along by feed inlet (111) to feeding screw section (124), precommpression section (125) and the self-built pressure section that slag notch (113) direction is sequentially distributed (126), the helical axis (121) includes the feeding section split axle (1211) being located on feeding screw section (124), is located at precommpression section (125) the precommpression section split axle (1212) on and the self-built pressure section split axle (1213) on self-built pressure section (126) are described to send Multiple helical blades (122) are mounted on material section split axle (1211) and precommpression section split axle (1212).

5. water plant dewatering system according to claim 4, it is characterised in that: the screw pitch of the precommpression section (125) by Feed inlet (111) to slag notch (113) direction is gradually reduced.

6. water plant dewatering system according to claim 4, it is characterised in that: pacify on the self-built pressure section split axle (1213) Equipped with back pressure ring (127).

7. water plant dewatering system according to claim 1, it is characterised in that: the spiral (12) and feed inlet (111) Corresponding one end is lower than spiral (12) one end corresponding with slag notch (113).

8. water plant dewatering system according to claim 1, it is characterised in that: it further include feed conveying device (2), it is described The discharge end of feed conveying device (2) is located at the top of the feed inlet (111) of squeezer (1).

9. water plant dewatering system according to claim 8, it is characterised in that: the feed conveying device (2) is belt Scale.

10. water plant dewatering system according to claim 1, it is characterised in that: further include material conveying device (3) out, institute State out material conveying device (3) feed end be located at squeezer (1) slag notch (113) lower section.