1. An electron emitting element comprising:
an electrode substrate and a thin-film electrode, which are provided so as to face each other; and
an electron acceleration layer sandwiched between the electrode substrate and the thin-film electrode,
the electron emitting element (i) accelerating electrons in the electron acceleration layer at a time when a voltage is applied between the electrode substrate and the thin-film electrode and (ii) emitting the electrons from the thin-film electrode,
the electron acceleration layer including a fine particle layer containing insulating fine particles to which fine particle layer a single material or a mixed material that facilitates electricity flow in a thickness direction of the fine particle layer is applied,
the electron acceleration layer including a conductive path formed therein in advance such that the conductive path runs through the electron acceleration layer in a thickness direction of the electron acceleration layer, the conductive path having an exit serving as an electron emitting section via which the electrons are supplied to the thin-film electrode,
the single material or the mixed material being conductive fine particles,
the conductive fine particles being deposited on a surface of the fine particle layer so as to form a deposition, and
the deposition of the conductive fine particles having a physical recess serving as the electron emitting section.
2. The electron emitting element as set forth in claim 1, wherein:
the single material or the mixed material is applied to the fine particle layer in a discrete manner when the fine particle layer is viewed from its top face where a side, of the fine particle layer, that faces the electrode substrate is regarded as a bottom face.
3. An electron emitting element comprising:
an electrode substrate and a thin-film electrode, which are provided so as to face each other; and
an electron acceleration layer sandwiched between the electrode substrate and the thin-film electrode,
the electron emitting element (i) accelerating electrons in the electron acceleration layer at a time when a voltage is applied between the electrode substrate and the thin-film electrode and (ii) emitting the electrons from the thin-film electrode,
the electron acceleration layer including a fine particle layer containing insulating fine particles to which fine particle layer a single material or a mixed material that facilitates electricity flow in a thickness direction of the fine particle layer is applied, and
the electron acceleration layer including a conductive path formed therein in advance such that the conductive path runs through the electron acceleration layer in a thickness direction of the electron acceleration layer, the conductive path having an exit serving as an electron emitting section via which the electrons are supplied to the thin-film electrode,
wherein the single material or the mixed material is applied to the fine particle layer in a discrete manner when the fine particle layer is viewed from its top face where a side, of the fine particle layer, that faces the electrode substrate is regarded as a bottom face,
wherein:
a total surface area of portions, in the fine particle layer, to which the single material or the mixed material is applied is not less than 5% but not more than 90.6% with respect to a surface area of the fine particle layer, and
the thin-film electrode has a thickness of not less than 100 nm but not more than 500 nm.
4. The electro emitting element as set forth in claim 3, wherein:
the total surface area of the portions, in the fine particle layer, to which the single material or the mixed material is applied is not less than 10% with respect to the surface area of the fine particle layer.
5. The electron emitting element as set forth in claim 3, wherein:
the thickness of the thin-film electrode is not less than 160 nm.
6. The electron emitting element as set forth in claim 1, wherein:
the fine particle layer further includes binder resin that binds the insulating fine particles to one another.
7. The electron emitting element as set forth in claim 1, wherein:
the conductive fine particles are noble metal.
8. The electron emitting element as set forth in claim 1, wherein:
the conductive fine particles contain at least any one of gold, silver, platinum, palladium, and nickel.
9. The electron emitting element as set forth in claim 1, wherein:
the thin-film electrode contains at least any one of gold, silver, carbon, tungsten, titanium, aluminum, and palladium.
10. An electron emitting element comprising:
an electrode substrate and a thin-film electrode, which are provided so as to face each other; and
an electron acceleration layer sandwiched between the electrode substrate and the thin-film electrode,
the electron emitting element (i) accelerating electrons in the electron acceleration layer at a time when a voltage is applied between the electrode substrate and the thin-film electrode and (ii) emitting the electrons from the thin-film electrode,
the electron acceleration layer including a fine particle layer containing insulating fine particles to which fine particle layer a single material or a mixed material that facilitates electricity flow in a thickness direction of the fine particle layer is applied,
the electron acceleration layer including a conductive path formed therein in advance such that the conductive path runs through the electron acceleration layer in a thickness direction of the electron acceleration layer, the conductive path having an exit serving as an electron emitting section via which the electrons are supplied to the thin-film electrode, and
the single material or the mixed material being a basic dispersant into which an electron donor that donates a pair of electrons is introduced as a substituent.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A ball pushing device for use with a ball hopper, comprising:
a housing having first and second ends, an opening for accepting balls and a ball chamber adjacent to the opening;
a motor coupled to the housing;
a pinion connected driven by the motor;
a rack having a ball engagement end, wherein the rack is slideably disposed within the housing and operably configured to engage and be driven by the pinion;
a first switch disposed in the housing and operably configured to activate the motor to rotate the pinion in a first direction and the first switch is activatable by the presence of a ball in the ball chamber;
a second switch disposed in the housing operably configured to activate the motor to rotate the pinion in an opposing second direction;
a third switch disposed in the housing at a predetermined distance from the second switch and operably configured to deactivate the motor; and,
a switch activation member disposed on the rack.
2. A ball pushing device, as recited in claim 1, wherein upon activation of the first switch, the motor rotates the pinion in the first direction causing the rack to push the ball out of the first end of the housing, the switch activation member travels with the housing until the activation member activates the second switch which then reverses the direction of the pinion in a second direction causing the movement of the rack towards the second end of the housing until the switch activation member strikes the third switch.
3. A ball pushing device, as recited in claim 1, wherein the first, second and third switches are electro-mechanical switches.
4. A ball pushing device, as recited in claim 1, wherein the ball engagement end of the rack is substantially planar and perpendicular to a longitudinal axis of the housing.
5. A hopper for use with a ball launching device, comprising:
a bin for holding balls;
a ball engagement portion having a housing having first and second ends, an opening for accepting balls and a ball chamber adjacent to the opening;
a chute connecting the bin and the ball engagement portion;
a motor coupled to the housing;
a pinion connected to and driven by the motor;
a rack having a ball engagement end, wherein the rack is slideably disposed within the housing and operably configured to engage and be driven by the pinion;
a first switch disposed adjacent to the rack and operably configured to activate the motor to rotate the pinion in a first direction and the first switch is activatable by the presence of a ball in the ball chamber;
a second switch disposed adjacent to the rack and operably configured to activate the motor to rotate the pinion in an opposing second direction;
a third switch disposed adjacent to the rack at a predetermined distance from the second switch and operably configured to deactivate the motor; and,
a switch activation member disposed on the rack.
6. A hopper, as recited in claim 5, wherein upon activation of the first switch the motor rotates the pinion in the first direction causing the rack to push the ball out of the first end of the housings the switch activation member travels with the rack until the switch activation member activates the second switch which then reverses the direction of the pinion in a second direction causing the movement of the rack towards the second end of the housing until the switch activation member strikes the third switch.
7. A hopper, as recited in claim 5, further comprising a swivel joint connecting the chute to the ball engagement portion, wherein the chute and the bin are rotatable about the ball engagement portion.
8. A hopper, as recited in claim 5, wherein the first, second and third switches are disposed in the housing.
9. A hopper, as recited in claim 5, further comprising a controller, wherein the controller transmits and receives radio frequency signals.
10. A ball hopper for use with a ball launching device, comprising:
a bin having an opening and an auger disposed adjacent to the opening in the bin;
a ball engagement device having a housing portion and a ball channel;
a chute having first and second ends connecting the opening of the bin and the ball channel of the ball engagement member;
a ball gate disposed along the length of the chute operably configured to be activated by a user; and,
a switch disposed adjacent to the gate and operably configured to deactivate the auger, the switch being activated by the presence of a ball at the gate.
11. A ball hopper, as recited in claim 10, further comprising a ball pushing member disposed adjacent the ball channel.
12. A ball hopper, as recited in claim 11, wherein the ball pushing member comprises at least one solenoid.
13. A ball hopper, as recited in claim 10, further comprising at least one support leg attached to at least one of the bin and the chute, and the at least one support leg being attachable to the ball launching device.
14. A ball hopper for use with a ball launching device, comprising:
a bin having an opening;
a delivery portion having a ball channel, the delivery portion is attachable to the ball launching device;
a chute having first and second ends, the first end is in communication with the opening of the bin and the second end is in communication with the ball channel;
a ball gate disposed along the length of the chute; and,
a ball pushing member disposed adjacent the ball channel, wherein activation of the ball gate allows a ball from the bin to travel through the chute into the ball channel of the delivery portion, and activation of the ball pushing member moves the ball out of the ball channel to the ball launching device.
15. A ball hopper, as recited in claim 14, further comprising:
an auger disposed adjacent the opening in the bin; and,
at least one support leg attached to at least one of the bin and the chute, and the at least one support leg being attachable to a ball directing device.
16. A ball hopper, as recited in claim 14 further comprising a swivel joint connecting the second end of the chute to the delivery portion, wherein the chute and the bin are rotatable about the delivery portion.
17. An automatic ball throwing device, comprising:
a ball directing assembly having a first member, a second member pivotally attached to the first member, a third member disposed substantially parallel to the second member and rotatably connected to the second member, a first actuator connected to the first and second members and a second actuator connected to the first and third members,
a ball hopper having a bin, a delivery portion and a chute connecting the bin to the delivery portion, the hopper being attached to the ball launching device and operably configured to deliver balls from the bin and through the chute and delivery portion to the ball launching device; and,
a ball launching device connected to the third member, wherein orientation of the ball launching device is controlled by actuation of the first and second actuators such that when the first actuator is actuated the second member pivots relative to the first member and when the second actuator is actuated the third member rotates relative to the second member.
18. An automatic ball throwing device, as recited in claim 17, wherein:
the bin is for holding balls;
the delivery portion has a housing having first and second ends, an opening for accepting balls and a ball chamber adjacent to the opening;
a motor is connected to the housing;
a pinion is connected to and driven by the motor;
a rack, has a ball engagement end, wherein the rack is slideably disposed within the housing and operably configured to engage and be driven by the pinion;
a first switch is disposed in the housing and operably configured to activate the motor to rotate the pinion in a first direction and the first switch is activatable by the presence of a ball in the ball chamber;
a second switch is disposed in the housing operably configured to activate the motor to rotate the pinion in an opposing second direction;
a third switch is disposed in the housing at a predetermined distance from the second switch and operably configured to deactivate the motor; and,
a switch activation member is disposed on the rack.
19. An automatic ball throwing device, as recited in claim 17, wherein:
the bin has an opening and an auger is disposed adjacent to the opening in the bin;
the delivery portion has a housing portion and a ball channel;
the chute has first and second ends connecting the opening of the bin and the ball channel of the deliver portion;
a ball gate is disposed along the length of the chute operably configured to be activated by a user; and,
a switch is disposed adjacent to the gate and operably configured to deactivate the auger, the switch being activated by the presence of a ball at the gate.
20. An automatic ball throwing device, as recited in claim 17, wherein:
the bin has an opening;
the delivery portion has a ball channel, the delivery portion is attachable to the ball launching device;
the chute has first and second ends, the first end is in communication with the opening of the bin and the second end is in communication with the ball channel;
a ball gate is disposed along the length of the chute; and,
a ball pushing member is disposed adjacent the ball channel, wherein activation of the ball gate allows a ball from the bin to travel through the chute into the ball channel of the delivery portion, and activation of the ball pushing member moves the ball out of the ball channel to the ball launching device.